WO2020093992A1 - Self-moving device, wireless charging station, automatic working system, and charging method therefor - Google Patents

Abstract

The present disclosure relates to a self-moving device, a wireless charging station, an automatic working system, and a charging method therefor. The self-moving device comprises: a wireless charging receiving module, configured to perform a charging operation on the basis of a wireless charging signal received from a wireless charging transmission module on the wireless charging station; a return guiding module, configured to detect guide information for guiding the self-moving device to move to the wireless charging station; an in-place sensing module, configured to sense the in-place guiding apparatus; and a first control module, configured to control, according to the detected guide information, the self-moving device to move to the wireless charging station, and configured to adjust operation parameters of the self-moving device upon sensing of the in-place guiding apparatus, the operating parameters including: an operating speed and/or an operating direction. The embodiments of the present disclosure can precisely guide the self-moving device.

Description

Self-mobile equipment, wireless charging station, automatic working system and charging method thereof

This application requires the priority of the Chinese patent application with the application date of November 5, 2018 and the application number of 201811307115.X, the entire content of which is incorporated by reference in this application.

Technical field

The present disclosure relates to the technical field of smart devices, and in particular, to a self-mobile device, a wireless charging station, an automatic working system, and a charging method thereof.

Background technique

At present, the self-propelled device is loved by the majority of users due to its intelligent characteristics, and it can be applied to all aspects of daily life, such as sweeping robots, smart cameras, flying machines, lawn mowers, etc., have been widely used application.

However, in the prior art, the self-propelled device cannot accurately return to the position of the wireless charging station to perform the charging operation when the power is insufficient or other charging is required. That is, in the prior art, there is a technical problem that the mobile device cannot accurately return to the position of the wireless charging station.

Summary of the invention

Embodiments of the present disclosure provide a self-mobile device, a wireless charging station, an automatic working system, and a charging method that can accurately return to the self-mobile device

According to a first aspect of the present disclosure, there is provided a self-mobile device that is charged by a wireless charging station, and a guide device in place is provided on the wireless charging station, and the self-mobile device senses the place by sensing The guidance device determines the location of the wireless charging station, and the self-mobile device includes:

A wireless charging receiving module configured to perform a charging operation based on the wireless charging signal received from the wireless charging transmitting module on the wireless charging station;

A regression guidance module configured to detect guidance information for guiding the self-mobile device to move to the wireless charging station;

An in-place sensing module configured to sense the in-place guidance device;

A first control module configured to control the self-mobile device to move to the wireless charging station based on the detected guide information, and configured to adjust the self-mobile device when the in-place guidance device is sensed Operating parameters, the operating parameters include: operating speed and / or operating direction.

In a possible implementation manner, the regression guidance module detects working area boundary information, and the first control module is configured to control the self-mobile device to move toward the wireless charging station along the boundary according to the boundary information.

In a possible implementation manner, the wireless charging station is connected to a guide line for generating the boundary information, and the guide information is generated by a power signal transmitted by the guide line; the first control module is configured to The guidance information detected by the regression guidance module controls the self-mobile device to move toward the wireless charging station along a guidance line.

In a possible implementation manner, the regression guide module includes two first detection units respectively disposed on both sides of the base of the self-moving device; the first control module is further configured to perform a charging operation Based on the phase and / or strength of the magnetic force signals detected by the two first detection units, the mobile device is guided to return to the wireless charging station along the guidance line.

In a possible implementation manner, the regression guidance module includes two second detection units respectively disposed on both sides of the base of the mobile device; the two second detection units detect grassland information to determine whether it is working Area boundary information, the first control module is configured to control the self-mobile device to move to the wireless charging station along the boundary of the working area according to the boundary information detected by the regression guidance module.

In a possible implementation manner, the second detection unit is a capacitive sensor.

In a possible implementation manner, the in-position guiding device includes a magnet assembly, and the in-place sensing module includes a magnetic detection element; the first control module is configured to detect the magnet assembly in the magnetic detection element When the magnetic field signal meets the first preset condition, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the magnet assembly includes a bar magnet assembly, and the bar magnet assembly includes a magnetic bar or a bar magnet assembly formed by arranging magnetic objects.

In a possible implementation manner, the first control module is configured to control the self-mobile device to reduce the running speed or control the self-mobile device when the magnetic detection element detects that the magnetic field signal of the magnet assembly meets the first preset condition The mobile device stopped working.

In a possible implementation manner, when the installation direction of the bar magnet assembly is perpendicular to the running direction of the mobile device, the bar magnet assembly includes at least two groups, and the first control module is configured to When the detection element detects that the magnetic field signal strength of the first group of bar magnet assemblies reaches the first preset threshold, the self-mobile device is controlled to reduce the running speed, and when it is detected that the magnetic field signal strength of the second group of bar magnet assemblies meets the second preset threshold Time control since the mobile device stopped running.

In a possible implementation manner, when the installation direction of the bar magnet assembly is parallel to the running direction of the self-moving device, the first control module is configured to detect that the magnetic field signal strength detected by the magnetic detection element complies with the third When the threshold is set, the self-mobile device is controlled to reduce the running speed, and when it is detected that the magnetic field signal strength meets the fourth preset threshold, the self-mobile device is controlled to stop running.

In a possible implementation manner, the in-position guidance device includes a wireless signal transmitting component, and the in-position sensing module includes a wireless signal receiving component, or the in-position guidance device includes a wireless signal receiving component, the in-position sensing module Including a wireless transmitting component; the first control module is configured to determine that the in-place guidance device is detected when the wireless signal receiving component detects the wireless signal generated by the wireless signal transmitting component.

In a possible implementation manner, the wireless signal transmitting component includes an RFID transmitter, and the wireless signal receiving component includes an RFID reader.

In a possible implementation manner, the in-place guidance device is an RFID transmitter, the in-place sensing module is an RFID reader, and when the RFID reader detects the radio frequency signal emitted by the RFID transmitter, it is determined to be detected The guiding device in place.

In a possible implementation manner, the in-place guidance device is an RFID reader, the in-place sensing module is an RFID transmitter, and a communication module for transmitting signals is also included between the wireless charging station and the mobile device When the RFID reader detects the radio frequency signal emitted by the RFID transmitter, and the mobile device receives the communication signal transmitted by the wireless charging station, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the in-place guidance device includes a wireless charging transmitting module, the in-place sensing module includes a coil induction module; the first control module is configured to output an equivalent impedance at the coil induction module When changing to a preset range, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the coil sensing module is a metal detection module, and the first control module is connected to the metal detection module to obtain an equivalent impedance output by the metal detection module.

In a possible implementation manner, the coil induction module includes an LC oscillator, and the first control module is connected to the LC oscillator to obtain an equivalent impedance of the LC oscillator.

In a possible implementation manner, the LC oscillator includes at least one of the following structures:

A first inductor, a first capacitor, a first resistor and a first oscillator connected in parallel;

A second inductor and a second oscillator connected in parallel;

A first coil and a first circuit coupled to the first coil, the first circuit includes a third inductor, a second resistor and a third oscillator connected in series, wherein the first coil is coupled to the third inductor Connect

A fourth inductor and a third resistor connected in series, and a second capacitor and a third oscillator connected in parallel on both sides of the fourth inductor and the third resistor.

In a possible implementation manner, the regression guidance module is further configured to detect the first position information from the mobile device, and the first control module is further configured to according to the pre-stored second position of the wireless charging station The information and the first location information guide the self-mobile device to move to the wireless charging station.

In a possible implementation manner, the in-position guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guidance assembly and an in-position assembly, and the in-position sensing module includes a guidance assembly detection unit and a detection unit for detecting the guidance assembly An in-place component detection unit of the in-place component;

The first control module is configured to guide the self-mobile device to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and control the self-mobile device to stop running based on the signal detected by the in-place component detection unit.

In a possible implementation manner, the guide assembly includes a coil assembly, and the first control module is configured to guide the mobile device along the coil assembly to the wireless charging transmitter module based on the magnetic force signal detected by the guide assembly detection unit mobile.

In a possible implementation manner, the in-place component includes a sensor component that interacts with the self-moving device or a mechanical structure component that abruptly changes the motion state of the self-moving device.

In a possible implementation manner, the in-position guiding device includes a ring assembly, the ring assembly includes an outer ring assembly and an inner ring assembly, a wireless charging transmitting module is provided in the inner ring assembly, and the in-place sensing module Including the outer ring detection unit for detecting the outer ring assembly and the inner ring detection unit for detecting the inner ring assembly;

The first control module is configured to adjust the posture of the self-mobile device based on the signal detected by the outer ring detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and based on the signal detected by the inner ring detection unit Control to stop running since the mobile device.

In a possible implementation manner, the outer ring detection unit includes a first outer ring detection unit and a second outer ring detection unit, and the first control module is configured to compare the detection of the first outer ring detection unit The signal and the signal detected by the second outer ring detection unit are controlled to enter the outer ring assembly from the mobile device based on the detected signal being consistent.

In a possible implementation manner, the outer ring assembly includes an outer ring coil and a signal generator for generating an electrical signal, the outer ring coil transmits current to form a magnetic signal, and the first control module is configured as When the phase or intensity of the magnetic signal of the outer ring coil detected by the first outer ring detection unit is consistent with the phase or intensity of the magnetic signal of the outer ring coil detected by the second outer ring detection unit, the mobile device is controlled to enter the outside Inside the ring coil.

In a possible implementation manner, the signal parameters transmitted by the inner ring component and the outer ring component are different.

In a possible implementation manner, the inner ring assembly includes a magnetic stripe, and the inner ring assembly detection unit includes a magnetic detection element.

In a possible implementation manner, the first control module is configured to receive the wireless charging signal sent by the wireless charging station through the wireless charging receiving module when the self-mobile device enters a coverage area corresponding to a predetermined charging position.

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

Detecting whether a wireless connection is established between the second communication module and the first communication module;

If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.

According to a second aspect of the embodiments of the present disclosure, there is provided a wireless charging station for charging a mobile device, which includes:

A first power module, which is used to provide power to the wireless charging station;

A wireless charging transmitting module, which is arranged in the charging area and is configured to transmit a wireless charging signal to the self-mobile device through the power provided by the first power module to charge the self-mobile device;

The wireless charging station is used in conjunction with a guidance device configured to generate guidance information for guiding the movement from the mobile device to the wireless charging station;

An in-place guidance device configured for the self-moving device to sense the in-place guidance device to determine the position of the wireless charging station, and adjust when the self-mobile device senses the in-place guidance device Operating parameters of the mobile device, the operating parameters including: operating speed and / or operating direction;

A second control module configured to control the wireless charging transmitting module to send a wireless charging signal to charge the self-mobile device.

In a possible implementation manner, the guidance device includes a guidance line for generating the guidance information, the wireless charging station is connected to the guidance line, and the guidance information is generated by a power signal transmitted by the guidance line; The self-mobile device controls the self-mobile device to move to the wireless charging station along the guide line based on the detected guide information.

In a possible implementation manner, the in-position guidance device includes a magnet assembly, for the self-moving device to determine that the in-position guidance is detected when the magnetic field signal of the magnet assembly meets a first predetermined condition Device.

In a possible implementation manner, the magnet assembly includes a bar magnet assembly that includes a magnetic bar or a bar magnet assembly formed by arranging magnetic objects.

In a possible implementation manner, when the installation direction of the bar magnet assembly is perpendicular to the running direction of the self-moving device, the bar magnet assembly includes at least two groups for the self-moving device to detect When the magnetic field signal strength of a group of bar magnet assemblies reaches the first preset threshold, the self-moving device is controlled to reduce the operating speed, and when the magnetic field signal strength of the second group of bar magnet assemblies meets the second preset threshold, the self-mobile device Stop running.

In a possible implementation manner, when the installation direction of the bar magnet assembly is parallel to the running direction of the self-moving device, the self-moving device controls when detecting that the magnetic field signal strength of the bar magnet assembly meets the third preset threshold The self-mobile device reduces the running speed and controls the self-mobile device to stop running when it detects that the magnetic field signal strength meets the fourth preset threshold.

In a possible implementation manner, the in-position guidance device includes a wireless signal transmission component, the self-moving device includes an in-position sensing module, the in-position sensing module includes a wireless signal reception component, or the in-position guidance device includes A wireless signal receiving component, the in-place sensing module includes a wireless transmitting component;

It is used for the self-mobile device to determine that the in-place guidance device is detected after the wireless signal receiving component detects the wireless signal generated by the wireless signal transmitting component.

In a possible implementation manner, the wireless signal transmitting component includes an RFID transmitter, and the wireless signal receiving component includes an RFID reader.

In a possible implementation manner, the in-place guidance device is an RFID transmitter, the in-place sensing module is an RFID reader, and when the RFID reader detects the radio frequency signal emitted by the RFID transmitter, it is determined to be detected The guiding device in place.

In a possible implementation manner, the in-place guidance device is an RFID reader, the in-place sensing module is an RFID transmitter, and a communication module for transmitting signals is also included between the wireless charging station and the mobile device When the RFID reader detects the radio frequency signal emitted by the RFID transmitter, and the mobile device receives the communication signal transmitted by the wireless charging station, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the in-place guidance device includes a wireless charging transmitting module, and the self-moving device includes a coil induction module; the equivalent impedance output by the self-moving device at the coil induction module changes to a preset In the range, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the coil sensing module is a metal detection module, and the equivalent impedance output by the metal detection module is obtained from the mobile device.

In a possible implementation manner, the coil induction module includes an LC oscillator, and the equivalent impedance of the LC oscillator is acquired from the mobile device.

In a possible implementation manner, the LC oscillator includes at least one of the following structures:

A first inductor, a first capacitor, a first resistor and a first oscillator connected in parallel;

A second inductor and a second oscillator connected in parallel;

A first coil and a first circuit coupled to the first coil, the first circuit includes a third inductor, a second resistor and a third oscillator connected in series, wherein the first coil is coupled to the third inductor Connect

A fourth inductor and a third resistor connected in series, and a second capacitor and a third oscillator connected in parallel on both sides of the fourth inductor and the third resistor.

In a possible implementation manner, the guidance apparatus includes a positioning module, and the self-mobile device is connected to a positioning module, and the self-mobile device uses the positioning module to locate based on the second location information of the wireless charging station as guidance information The first location information from the mobile device and the second location information control the autonomous mobile device to move toward the wireless charging station, and the location information of the wireless charging station includes a pre-stored location of the wireless charging station.

In a possible implementation manner, the in-position guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guidance assembly and an in-position assembly, and the self-moving device includes a guidance assembly detection unit and an inspection station that detect the guidance assembly The in-place component detection unit of the in-place component;

The self-moving device guides the self-mobile device to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and controls the self-mobile device to stop running based on the signal detected by the in-place component detection unit.

In a possible implementation manner, the guide assembly includes a coil assembly, and the self-moving device guides the self-mobile device to move along the coil assembly to the wireless charging transmitting module based on the magnetic force signal detected by the guide assembly detection unit.

In a possible implementation manner, the in-place component includes a sensor component that interacts with the self-moving device or a mechanical structure component capable of abruptly changing the motion state of the self-moving device.

In a possible implementation manner, the in-place guidance device includes a ring assembly, the ring assembly includes an outer ring assembly and an inner ring assembly, a wireless charging transmitter module is provided in the inner ring assembly, and the self-moving device includes The outer ring detection unit for detecting the outer ring assembly and the inner ring detection unit for detecting the inner ring assembly;

The self-moving device adjusts the posture of the self-mobile device based on the signal detected by the outer ring detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and controls the self-movement based on the signal detected by the inner ring detection unit The device stops running.

In a possible implementation manner, the outer ring detection unit includes a first outer ring detection unit and a second outer ring detection unit, and the first control module of the mobile device is configured to compare the first outer ring detection The signal detected by the unit and the signal detected by the second outer ring detection unit are controlled to enter the outer ring assembly from the mobile device based on the coincidence of the detected signal.

In a possible implementation manner, the outer ring assembly includes an outer ring coil and a signal generator for generating a point signal, the outer ring coil transmits current to form a magnetic signal, and the first control module is configured as When the phase or intensity of the magnetic signal of the outer ring coil detected by the first outer ring detection unit is consistent with the phase or intensity of the magnetic signal of the outer ring coil detected by the second outer ring detection unit Inside the ring coil.

In a possible implementation manner, the signal parameters transmitted by the inner ring component and the outer ring component are different.

In a possible implementation manner, the inner ring assembly includes a magnetic stripe, and the inner ring detection unit includes a magnetic detection element.

In a possible implementation manner, the wireless charging and transmitting module includes a resonant coil assembly.

In a possible implementation manner, the wireless charging station includes a hollow bottom plate.

In a possible implementation manner, when the self-mobile device enters a coverage range corresponding to a predetermined charging position, the second control module is configured to control the wireless charging transmitting module to send a wireless charging signal to charge the self-mobile device.

In a possible implementation manner, the wireless charging station includes a second communication module, and the mobile device includes a first communication module;

Detecting whether a wireless connection is established between the second communication module and the first communication module;

If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.

In a possible implementation manner, the wireless charging station includes a second communication module, and the mobile device includes a first communication module;

Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.

According to a third aspect of the embodiments of the present disclosure, there is provided a wireless charging station for charging a mobile device, which includes:

A first power module, which is used to provide power to the wireless charging station;

A wireless charging transmitting module configured to transmit a wireless charging signal to the self-mobile device through the power provided by the first power module to charge the self-mobile device;

The wireless charging station is used in conjunction with a guidance device, and the guidance device is configured to generate guidance information for guiding the movement from the mobile device to the wireless charging station;

A guiding device in place, which includes a ring assembly including an outer ring assembly and an inner ring assembly disposed inside the outer ring assembly, the wireless charging transmitter module is located in the inner ring assembly, and the self-mobile device Adjust the posture of the self-mobile device based on the sensed signal of the outer ring component to guide the self-mobile device to move toward the wireless charging transmitting module, and control the self-mobile device to reduce the running speed based on the sensed signal of the inner ring component or Stop running

A second control module configured to control the wireless charging transmitting module to send a wireless charging signal to charge the self-mobile device.

According to a fourth aspect of the embodiments of the present disclosure, there is provided an automatic working system including the self-mobile device according to any one of the first aspect and the wireless according to any one of the second aspect or the third aspect charging station.

According to a fifth aspect of the embodiments of the present disclosure, there is provided a wireless charging method of an automatic working system, the automatic working system includes a self-mobile device and a wireless charging station, the wireless charging station and a guiding device for generating a guiding signal Coordinated use, the wireless charging station is provided with a guiding device in place, the method includes:

Detect the pilot signal;

Controlling the self-mobile device to move toward the wireless charging station when the guidance signal is detected;

Sensing a guiding device in place on the wireless charging station;

Adjusting the operating parameters of the self-moving device when the in-place guidance device is sensed, the operating parameters including: operating speed and / or operating direction;

The wireless charging station is controlled to transmit a wireless charging signal to charge the mobile device.

In a possible implementation manner, the in-place guidance device includes a magnet assembly, and the sensing in-place guidance device provided on the wireless charging station includes:

Detecting the magnetic field signal of the magnet assembly by a magnetic detection element;

When the magnetic detection element detects that the magnetic field signal of the magnet assembly meets the first preset condition, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the in-place guidance device includes a wireless signal transmission component, and the sensing in-place guidance device provided on the wireless charging station includes:

When the wireless signal generated by the wireless signal transmitting component is detected by the wireless signal receiving component, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the in-position guidance device includes a wireless signal receiving component, and the sensing in-position guidance device provided on the wireless charging station includes:

When the wireless signal generated by the wireless signal transmitting component is detected by the wireless signal receiving component, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the in-place guidance device includes a wireless charging transmitting module, and the sensing in-place guidance device provided on the wireless charging station includes:

When the equivalent impedance output by the coil induction module changes to a preset range, it is determined that the in-place guidance device is detected.

In a possible implementation manner, the in-position guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guidance assembly and an in-position assembly, and the sensing in-position guidance device provided on the wireless charging station includes:

The self-mobile device is guided to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and the self-mobile device is controlled to stop running based on the signal detected by the in-place component detection unit.

In a possible implementation manner, the in-place guide device includes a ring assembly, the ring assembly includes an outer ring assembly and an inner ring assembly, a wireless charging transmitter module is provided in the inner ring assembly, and the sensing The in-place guidance device provided on the wireless charging station includes:

The posture of the self-mobile device is adjusted based on the signal detected by the outer loop detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and the self-mobile device is controlled to stop running based on the signal detected by the inner loop detection unit.

In a possible implementation manner, the method further includes:

When the self-mobile device enters the coverage area corresponding to the predetermined charging position, the wireless charging signal sent by the wireless charging station is received by the wireless charging receiving module.

According to a sixth aspect of the embodiments of the present disclosure, a wireless charging method for an automatic working system is provided, the automatic working system includes a self-mobile device and a wireless charging station, characterized in that the wireless charging station is used to generate guidance The signal guiding device is used in conjunction, and the wireless charging station is provided with a guiding device in place. The method includes:

Detect the pilot signal;

Controlling the self-mobile device to move toward the wireless charging station when the guidance signal is detected;

Sensing an in-place guidance device provided on the wireless charging station, wherein the in-place guidance device includes a ring assembly including an outer ring assembly and an inner ring assembly disposed inside the outer ring assembly, and the wireless transmission module is located Inside the inner ring assembly;

Adjust the posture of the self-mobile device based on the sensed signal of the outer ring component to guide the self-mobile device to move toward the wireless transmission module, and control the self-mobile device to reduce the running speed or stop based on the sensed signal of the inner ring component run;

The wireless charging station is controlled to transmit a wireless charging signal to charge the mobile device.

According to a seventh aspect of the embodiments of the present disclosure, there is provided a self-mobile device which is charged by a wireless charging station, which is characterized by comprising:

A wireless charging receiving module configured to perform a charging operation based on the wireless charging signal received from the wireless charging station;

The first control module is configured to receive the wireless charging signal sent by the wireless charging station through the wireless charging receiving module when the self-mobile device enters the coverage corresponding to the predetermined charging position.

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

Detecting whether a wireless connection is established between the second communication module and the first communication module;

If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.

In a possible implementation manner, the self-mobile device includes a first request module, and the first request module sends a request signal to the wireless charging station;

After the wireless charging station receives the request signal, the wireless charging station charges the self-mobile device.

In a possible implementation manner, the self-mobile device includes a response module, the wireless charging station sends a request signal to the self-mobile device, and the response module returns a response signal according to the request signal sent by the wireless charging station ;

After the wireless charging station receives the response signal matched with the request signal by the response module, the wireless charging station charges the self-mobile device.

In a possible implementation manner, after the self-mobile device enters the coverage range corresponding to the predetermined charging position, the first control module is configured to control the self-mobile device to decrease the running speed and move to the predetermined charging position.

In a possible implementation manner, after the mobile device enters a coverage area corresponding to a predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.

In a possible implementation manner, a detection module is further included. During the charging process, the detection module detects whether the charging of the self-mobile device is completed, and if the charging is completed, the wireless charging station is controlled to enter a low power Consuming mode.

According to an eighth aspect of an embodiment of the present disclosure, there is provided a wireless charging station for charging a mobile device, which includes:

A first power module, which is used to provide power to the wireless charging station;

A wireless charging transmitting module configured to transmit a wireless charging signal to the self-mobile device through the power provided by the power supply module to charge the self-mobile device;

A second control module configured to switch on the first power module and the wireless charging transmitting module when the self-mobile device enters the coverage range corresponding to the predetermined charging position to start the wireless charging transmitting module to the self-mobile device Transmit wireless charging signal.

In a possible implementation manner, the wireless charging station includes a second communication module, and the mobile device includes a first communication module;

Detecting whether a wireless connection is established between the second communication module and the first communication module;

If the second communication module successfully establishes the wireless connection with the first communication module, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.

In a possible implementation manner, the wireless charging station includes a second communication module, and the mobile device includes a first communication module;

Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.

In a possible implementation manner, the wireless charging station includes a receiving module, and the self-mobile device sends a request signal to the wireless charging station;

After the receiving module receives the request signal, the second control module is configured to charge the self-mobile device to the wireless charging station.

In a possible implementation manner, the wireless charging station includes a second request module and a receiving module, and the second request module sends a request signal to the self-mobile device;

After the receiving module receives the response signal matched by the self-mobile device and matching the request signal, the second control module is configured to control the wireless charging station to charge the self-mobile device.

In a possible implementation manner, after the self-mobile device enters the coverage range corresponding to the predetermined charging location, the second control module controls the self-mobile device to decrease the running speed and move to the predetermined charging location.

In a possible implementation manner, after the mobile device enters a coverage area corresponding to a predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.

In a possible implementation manner, a detection module is further included. During the charging process, the detection module detects whether the charging of the self-mobile device is completed, and if the charging is completed, the wireless charging station is controlled to enter a low power Consuming mode.

According to a ninth aspect of the embodiments of the present disclosure, there is provided an automatic working system including the self-mobile device according to any one of the seventh aspects of the claims and the wireless charging station according to any one of the eighth aspects.

According to a tenth aspect of an embodiment of the present disclosure, a charging method for an automatic working system is provided, which is applied in a self-working system, the self-working system includes a self-mobile device and a wireless device that performs a charging operation for the self-mobile device Charging station, the method includes:

Determining whether the self-mobile device enters the coverage range corresponding to the predetermined charging location;

If yes, the wireless charging transmitting module is activated to transmit a wireless charging signal to charge the self-mobile device.

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module; the determining whether the coverage range corresponding to the self-mobile device entering a predetermined charging location includes :

Detecting whether a wireless connection is established between the second communication module and the first communication module;

If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module; the determining whether the coverage range corresponding to the self-mobile device entering a predetermined charging location includes :

Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.

In a possible implementation manner, the wireless charging station includes a receiving module, and the method further includes:

The self-mobile device sends a request signal to the wireless charging station;

After the receiving module receives the request signal, the wireless charging station charges the self-mobile device.

In a possible implementation manner, the self-mobile device includes a response module, and the method further includes:

The wireless charging station sends a request signal to the self-mobile device, and the response module returns a response signal according to the request signal sent by the wireless charging station;

After the wireless charging station receives the response signal matched with the request signal by the response module, the wireless charging station charges the self-mobile device.

In a possible implementation manner, the method further includes:

After the self-mobile device enters the coverage area corresponding to the predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.

In a possible implementation manner, the method further includes:

During the charging process, it is detected whether the charging of the self-mobile device is completed;

If the charging is completed, the wireless charging station is controlled to enter a low power consumption mode.

In the embodiments of the present disclosure, it is possible to realize the return from the mobile device to the wireless charging station according to the guidance information through the setting of the return guidance device and the in-place guidance device, and can be accurately docked to the wireless charging transmitter module, with the effect of precise positioning. In addition, the embodiments of the present disclosure can also start the wireless charging receiving module or the wireless charging transmitting module when the mobile device enters the coverage corresponding to the charging position, thereby effectively reducing the power consumption of the wireless charging station or the mobile device.

It should be understood that the above general description and the following detailed description are only exemplary and explanatory, rather than limiting the present disclosure.

Other features and aspects of the present disclosure will become clear from the following detailed description of exemplary embodiments with reference to the accompanying drawings.

BRIEF DESCRIPTION

The drawings herein are incorporated into and constitute a part of this specification, and these drawings show embodiments consistent with the present disclosure and are used to explain the technical solutions of the present disclosure together with the description.

FIG. 1 shows a block diagram of a mobile device according to an embodiment of the present disclosure;

2 shows a schematic diagram when docking from a mobile device to a wireless charging station according to an embodiment of the present disclosure;

3 shows another block diagram of a self-mobile device according to an embodiment of the present disclosure;

4 shows a schematic diagram of a return wireless charging station from a mobile device according to an embodiment of the present disclosure;

FIG. 5 shows a schematic structural diagram of an in-place guidance device of a wireless charging station according to an embodiment of the present disclosure;

6 shows another schematic structural view of the in-place guidance device of the wireless charging station according to the embodiment of the present disclosure;

7 shows a schematic diagram of detecting a wireless transmission module from a coil induction module of a mobile device according to an embodiment of the present disclosure;

8 shows another schematic diagram of detecting a wireless transmission module from a coil induction module of a mobile device according to an embodiment of the present disclosure;

9 shows a schematic diagram of a process of returning to docking from a mobile device to a wireless charging station according to an embodiment of the present disclosure;

10 is a schematic diagram of another direction of FIG. 9;

11 shows a schematic diagram of the structural composition of an LC oscillator according to an embodiment of the present disclosure;

12 is a schematic diagram of another structural composition of an LC oscillator according to an embodiment of the present disclosure;

13 is a schematic diagram of another structural composition of an LC oscillator according to an embodiment of the present disclosure;

14 is a schematic diagram of another structural composition of an LC oscillator according to an embodiment of the present disclosure;

15 shows another schematic structural view of the in-place guidance device 201 of the wireless charging station according to an embodiment of the present disclosure;

FIG. 16 shows another structural schematic diagram of the in-place guidance device 201 of the wireless charging station according to an embodiment of the present disclosure;

17 shows a block diagram of a wireless charging station according to an embodiment of the present disclosure;

18 shows another block diagram of a wireless charging station according to an embodiment of the present disclosure;

19 shows a flowchart of a wireless charging method of an automatic working system according to an embodiment of the present disclosure;

20 shows another flowchart of a wireless charging method of an automatic working system according to an embodiment of the present disclosure;

21 shows a block diagram of a mobile device according to an embodiment of the present disclosure;

22 shows another block diagram of a self-mobile device according to an embodiment of the present disclosure;

23 shows yet another block diagram of a self-mobile device according to an embodiment of the present disclosure;

24 shows a block diagram of a wireless charging station according to an embodiment of the present disclosure;

FIG. 25 shows a flowchart of a charging method of an automatic working system according to an embodiment of the present disclosure.

detailed description

Various exemplary embodiments, features, and aspects of the present disclosure will be described in detail below with reference to the drawings. The same reference numerals in the drawings denote elements having the same or similar functions. Although various aspects of the embodiments are shown in the drawings, unless specifically noted, the drawings are not necessarily drawn to scale.

The specific word "exemplary" here means "used as an example, embodiment, or illustrative". Any embodiments described herein as "exemplary" need not be interpreted as superior or better than other embodiments.

The term "and / or" in this article is just an association relationship that describes an associated object, indicating that there can be three relationships, for example, A and / or B, which can mean: A exists alone, A and B exist at the same time, exist alone B these three cases. In addition, the term “at least one” herein means any one of the plurality or any combination of at least two of the plurality, for example, including at least one of A, B, and C, may mean including from A, Any one or more elements selected from the set consisting of B and C.

In addition, in order to better illustrate the present disclosure, numerous specific details are given in the specific implementations below. Those skilled in the art should understand that the present disclosure can also be implemented without certain specific details. In some examples, methods, means, components and circuits well known to those skilled in the art are not described in detail in order to highlight the gist of the present disclosure.

FIG. 1 shows a block diagram of a self-mobile device according to an embodiment of the present disclosure, where the self-mobile device provided by the embodiment of the present disclosure may be a device capable of traveling automatically, which may include any intelligent robot, such as an intelligent sweeper, An intelligent snow sweeper, an intelligent lawn mower, an intelligent sprinkler, an intelligent camera robot, etc., can be used as a self-moving device as long as they can automatically walk.

The embodiments of the present disclosure may configure a wireless charging station for the automatic mobile device, and the wireless charging station may be used to charge the automatic device, that is, provide power for the automatic device. Since the mobile device can move to work in the working area according to the type of the device, it will move to the wireless charging station when the charging conditions are satisfied to perform the charging operation through the wireless charging station.

As shown in FIG. 1, the self-mobile device 100 according to an embodiment of the present disclosure may include:

The wireless charging receiving module 101 is configured to perform a charging operation based on the wireless charging signal received from the wireless charging transmitting module on the wireless charging station;

Regression guidance module 102, which is configured to detect guidance information for guiding movement from the mobile device to the wireless charging station;

The in-place sensing module 103 is configured to sense the in-place guidance device;

The first control module 104 is configured to control the mobile device to move to the wireless charging station according to the detected guidance information, and is configured to adjust the operating parameters of the mobile device when the in-place guidance device is sensed. The operating parameters include: operating Speed and / or direction of travel.

Wherein, the wireless charging station that performs the charging operation for the mobile device may include an in-place guidance device, and the self-mobile device may determine the position of the wireless charging station by sensing the in-place guidance device during the movement to the wireless charging station. FIG. 2 shows a schematic diagram when docking from a mobile device to a wireless charging station according to an embodiment of the present disclosure. Wherein, the charging base plate 203 of the wireless charging station 200 may include an in-place guiding device 201 and a wireless charging transmitting module 202, wherein the wireless charging transmitting module 202 is used to transmit a wireless charging signal, since the mobile device moves to the charging area of the wireless charging station At this time, the charging operation can be performed through the wireless charging signal transmitted by the wireless charging transmitting module.

As described in the above embodiment, the self-mobile device can detect the guide information that guides it to move to the wireless charging station 200 through the regression guide module 102, and the position of the wireless charging station can be determined through the guide information, thereby enabling the autonomous mobile device to move to wireless charging Guided return of the station. At the same time, the self-moving device can also sense that the in-place guidance device 201 determines that it is about to arrive or has reached the wireless charging station 200 through the in-place sensing module 103, thereby performing the adjustment of the operating parameters.

In a possible implementation manner, the self-mobile device may determine whether the charging condition is satisfied according to the remaining power, and when the charging condition is met, control the regression guidance module to detect the guidance information. FIG. 3 shows another block diagram of a self-mobile device according to an embodiment of the present disclosure. As shown in FIG. 3, compared with the embodiment of FIG. 1, the self-mobile device in the embodiment of the present disclosure may further include a detection module 105 and a power module 106, wherein the detection module 105 may be used to detect whether the self-mobile device satisfies charging condition. The power supply module 106 is used to provide power for the operation of the mobile device. It can be connected to the wireless charging receiving module 101 to perform the charging operation of the power supply module 106 through the wireless charging signal received by the wireless charging receiving module 101. The detection module 105 may be connected to the power module 106 to obtain the current remaining power value of the power module 106, and may determine whether the charging condition is satisfied according to the detected remaining power value, for example, it may be determined whether the remaining power value exceeds the reference power If the reference power is exceeded, the charging conditions are not met. If the reference power is not exceeded, the charging conditions are met. The reference power can be set according to the battery capacity and charging requirements of the power module, and specific values are not limited in the embodiments of the present disclosure. Alternatively, the detection module 105 may also determine whether the charging condition is satisfied according to the ratio between the remaining power and the power supply capacity, wherein when the ratio is greater than the reference ratio, it is determined that the charging condition is not satisfied, and when the ratio is less than the reference ratio, it is determined to be satisfied For charging conditions, the reference ratio can also be set according to the power capacity of the device and the charging demand, for example, it can be set to 10%, etc., and the present disclosure does not specifically limit it.

In another possible implementation manner, the detection module 105 may also determine that the charging condition is satisfied according to the received charging instruction. As shown in FIG. 3, the self-mobile device may further include a first communication module 107, which may perform communication with other devices. For example, the first communication module 107 may include a Bluetooth unit, a wifi unit, or other communication units, as long as it can perform a communication operation, it may serve as the first communication module 107 in the embodiment of the present disclosure. The first communication module 107 can receive the charging control instruction transmitted by other devices (such as a controller) and transmit the charging control instruction to the detection module 105, and when the detection module receives the charging control instruction, it can determine that the mobile device satisfies the charging condition. In addition, the detection module 106 can also detect the instruction information input by the user. For example, an input module 108 can be provided on the mobile device. The input module can include input interfaces such as a touch screen, a keyboard, and a voice input module. The user can input through the input module Control instructions, such as charging control instructions, power-on instructions, and power-off instructions, are used to control instructions from the mobile device. The detection module 106 may be connected to the input module 108 to receive the charging control instruction transmitted by the input module 108, and when receiving the charging control instruction, it may be determined that the charging condition is satisfied.

The above is only an example of the case where the charging condition is satisfied. In other embodiments of the present disclosure, whether the charging condition is satisfied can be determined in other ways. The present disclosure does not specifically limit this as long as the charging condition can be determined, that is, Can serve as an embodiment of the present disclosure.

When it is detected that the charging condition is satisfied, the first control module 104 can detect the guidance information through the regression guidance module 102. The regression guidance module 104 of the embodiment of the present disclosure may determine the guidance information by detecting the working area boundary information from the mobile device, or may also determine the guidance information by the obtained second location information of the wireless charging station.

4 shows a schematic diagram of a return wireless charging station from a mobile device according to an embodiment of the present disclosure. Among them, a guide line 109 for generating boundary information is enclosed at the boundary of the working area of the mobile device. The guide line 109 can be electrically connected to the wireless charging station 200. Since the wireless charging station 200 can supply power to the guide line 109, the Power is transmitted in the guide wire 109, and the power signal transmitted based on the guide wire can generate guide information. For example, the power transmitted in the guide wire can generate an electromagnetic field around the guide wire. The guide information can be a magnetic signal of the electromagnetic field, and then return to the guide module 102 may detect the magnetic force signal as guidance information, and the first control module 104 may receive the guidance information detected by the regression guidance module 102 and control the self-mobile device to move to the wireless charging station 200 along the guidance line according to the detected guidance information. In a possible implementation manner, the regression guidance module 102 may include two first detection units disposed on both sides of the charging base 203 of the mobile device, and the two first detection units may respectively detect magnetic signals as guidance information, The first detection unit may include a magnetic force sensor. Wherein, since the mobile device does not reach the position of the guide line 109 in the working area, the first control module 104 may determine the position of the guide line according to the strength of the magnetic signal detected by the two first detection units, because the closer to the guide line The stronger the strength of the magnetic signal of the position, the movement from the mobile device to the guide wire can be controlled according to the strength of the magnetic signal detected by the first detection unit.

When the self-mobile device moves to the position of the guide line, the first control unit may control the self-mobile device to move to the wireless charging station along the guide line according to the strength of the magnetic force signals detected by the two first detection units. Similarly, during the movement along the guide line, the first control module 104 can control the mobile device to move in the same direction as the strength of the magnetic signal detected by the two first detection units and the strength of the magnetic signal collected in real time, Thereby, it can move to the wireless charging station along the guide line.

Or, in another embodiment of the present disclosure, the regression guidance module 102 can use the phase of the magnetic force signal as guidance information, and the first control module can also control the self-movement according to the phase of the magnetic force signal detected by the two first detection units The device moves along the guide line, where the first detection unit can separately detect the phase value of the magnetic force signal, and when the phase values of the magnetic force signals detected by the two first detection units are consistent, it indicates that the two first detection units are symmetrically located in the guide On both sides of the line, the first control module can control the self-moving device to move in the direction in which the magnetic signals detected by the two first detection units are in phase.

In another embodiment, the first control module 104 can control the movement of the mobile device to the position of the guide line according to the strength of the magnetic signals detected by the two first detection units, and then according to the magnetic signals detected by the two first detection units The phase control of the mobile device moves along the direction in which the magnetic signals detected by the two first detection units are in the same phase. This method can control the regression of the mobile device across the guide line. The left and right swings can be within ± 20mm, and the final movement Go to the location of the wireless charging station and dock with the wireless charging station.

According to an embodiment of the present disclosure, the first control module 104 can control the mobile device to move along the guide line 109 to the wireless charging station 200, while the in-place sensing module 103 can sense the in-place guidance device 201 in the wireless charging station 200, the in-place guidance The device 201 may be disposed in the vicinity of the wireless charging transmitting module 202, or configured as the wireless charging transmitting module 202, so that when the in-position guiding device 201 is sensed, the first control module 104 executes the control of slowing down or stopping operation from the mobile device .

In another embodiment of the present disclosure, the above-mentioned guide line may not be provided, and the regression guide module 102 may also be used to detect whether the self-mobile device is at the boundary of the working area, so that the first control module may control the self-mobile device along the The boundary of the working area moves. That is, the regression guidance module 102 may also use the detected grassland information as guidance information. The regression guidance module 102 may include two second detection units respectively disposed on both sides of the base of the mobile device. The two second detection units may be used to detect grassland information to determine whether it is work area boundary information, for example, The second detection unit may include a camera and an image recognition unit, and the image acquired from the camera may be transmitted to the image recognition unit. The image recognition unit may recognize whether the obtained image includes grass, and transmit the recognition result to the first control module. Wherein, the first control module can determine that the position from the mobile device is the boundary of the working area when one second detection unit recognizes the grass and the image of the other second detection unit does not include the grass, then the mobile device can be controlled It moves along the grassland detected by one of the two second detection units while the other detection unit cannot detect the grassland, so that it can move to the wireless charging station according to the boundary of the working area.

Alternatively, the second detection unit of the embodiment of the present disclosure may also be a capacitance sensor. Since the capacitance sensor may contact the grass, thereby detecting the capacitance value of the grass, the first control module 104 may be based on the detections of the two second detection units. The capacitance value determines whether the mobile device is in the working area or at the boundary of the working area. Among them, if the capacitance values detected by the two detection units are the same and are pre-stored capacitance values, it indicates that since the mobile device is in the working area, if the capacitance values detected by the two detection units are the same and are not pre-stored capacitances Value, indicating that the mobile device has moved to the outside of the work area. At this time, the first control module can control the movement direction of the mobile device to move into the work area. In addition, if one of the two second detection units detects The capacitance value is a pre-stored capacitance value, and when the capacitance value detected by another second detection unit is not the pre-stored capacitance value, it can be determined that the mobile device is located at the boundary of the working area at this time, and the first control module 104 can control The mobile device moves along the boundary of the work area.

In another possible implementation manner, the regression guidance module may detect the first location information from the mobile device. For example, the regression guidance module may further include a GPS positioning unit, which is used to acquire the location from the mobile device. And the second location information of the wireless charging station may also be stored in the mobile device, or the wireless charging station may also send its second location information to the outside, and the mobile device may receive the second location information. Correspondingly, the second control module may guide the self-mobile device to move to the wireless charging station according to the first position information of the self-mobile device detected by the regression guidance module and the second position information of the wireless charging station stored in the mobile device. The second control module may use the difference between the first position information and the second position information as guidance information, and adjust the running direction of the mobile device according to the difference, and move to the wireless charging station.

According to an embodiment of the present disclosure, the guidance information acquired through the regression guidance module 102 can be implemented to control the movement from the mobile device to the wireless charging station. The above embodiment is only an exemplary description of the regression guidance module. In other embodiments of the present disclosure, the regression guidance module may also obtain guidance information in other ways, so that the first control module controls the mobile device to the wireless charging station according to the guidance information mobile.

When the self-mobile device moves toward the wireless charging station, it can sense the in-place guidance device provided in the wireless charging station, and can reduce the running speed of the self-mobile device when sensing the in-place sensing device, or control the self-mobile device to stop moving. The in-place guidance device will be described in detail below.

FIG. 5 shows a schematic structural diagram of an in-place guidance device of a wireless charging station according to an embodiment of the present disclosure. Among them, in a possible implementation manner, the in-place guide device 201 may be provided in the charging base 203 of the wireless charging station and the in-place guide device 201 may include a magnet assembly, and correspondingly, from the in-place sensing module in the mobile device 100 103 may include a magnetic detection element, which may detect the magnetic field signal of the magnet and transmit the parameter value of the magnetic field signal to the first control module 104, wherein the parameter value of the magnetic field signal may include the magnetic force value of the magnetic field, that is, the magnetic field signal Magnetic field strength. The magnetic detection element may include a magnet sensor or other device capable of detecting the magnetic force of the magnet, which is not limited in the embodiments of the present disclosure. The first control module 104 can receive the parameter value of the magnetic field signal transmitted by the magnetic detection element, and when the parameter value of the magnetic field signal detected by the magnetic detection element meets the first preset condition, determine that the guide device 201 has reached the position from the mobile device. The operating parameters of the mobile device can be adjusted.

Wherein, the wireless charging transmitting module 202 and the in-place guiding device 201 are both provided in the charging base 203, and the in-place guiding device 201 may also be provided at the bottom of the charging base, so as to avoid the influence on the movement from the mobile device. In addition, the charging base 203 and the self-mobile device can be installed flush with the ground on the side where the charging operation is performed, or embedded in the ground without protruding from the ground, so that the influence on the self-mobile device can be further avoided.

In addition, when determining that the magnetic field strength of the received magnetic field signal is greater than or equal to the reference strength value, the first control module 104 determines that the magnetic field signal satisfies the first preset condition. It may also be determined that the magnetic field signal satisfies the first preset condition according to the relationship of the magnetic field strength, and the magnetic field signal satisfies the first preset condition. The reference strength value or the reference strength relationship may be determined according to the magnetism, quantity, and arrangement of the set magnet assembly. The embodiment may set different reference intensity values or reference intensity relationships according to requirements and the above variables, that is, the embodiments of the present disclosure do not specifically limit this, as long as the intensity values or intensity relationships can indicate the movement from the mobile device to the in-place guidance device It can be used as an embodiment of the present disclosure.

In addition, in the embodiment of the present disclosure, the magnet assembly configured to guide the device 201 in the charging base 203 includes a bar magnet assembly, and the bar magnet assembly may include at least one magnetic bar or a bar magnet assembly arranged by magnetic objects And the at least one magnetic stripe or magnetic object can be installed on the charging base 203 in sequence. For example, they are sequentially arranged in the horizontal direction, or may be arranged in the vertical direction, which is not limited in the present disclosure.

Based on the above configuration, when the in-position sensing module 103 moving from the mobile device senses the in-position guidance device 201, it indicates that the mobile device has moved to the position of the wireless charging station 200, and the first control module 104 can control the The mobile device reduces the running speed or controls the mobile device to stop running.

In one of the embodiments shown in FIG. 5, when the mounting direction of the magnetic strip or magnetic object in the strip magnet assembly is perpendicular to the running direction of the self-moving device, the strip magnet assembly includes at least two groups, such as the first group The strip magnet assembly and the second set of strip magnet assemblies, and the first set of strip magnet assemblies pass from the mobile device first. Correspondingly, the first control module 104 can control the self-mobile device to reduce the running speed when the magnetic detection element detects that the magnetic field signal strength of the first group of bar magnet assemblies reaches the first preset threshold, and detects the second group of bar magnets When the magnetic field signal strength of the component meets the second preset threshold, the self-mobile device is controlled to stop running. The first preset threshold and the second preset threshold may be determined according to the number of magnet assemblies installed in each group and the position of the wireless charging transmitter module 202, which is not limited in the present disclosure. That is to say, the embodiments of the present disclosure can accurately locate the wireless charging transmitting module 202 of the wireless charging station according to the change of the magnetic field signal strength of the provided magnet assembly.

In another embodiment, when the number of the bar magnet assembly includes multiple groups, for example, the third magnetic stripe is the stop position, when the third magnetic stripe is walked over from the mobile device, it can also be moved back and restarted Check the bar magnet assembly and re-connect.

In another embodiment, when the number of bar magnet assemblies is one set, the operating speed is reduced when a magnetic field signal is detected, and the mobile device stops operating when the magnetic field strength meets a certain value.

In addition, as shown in FIG. 6, the mounting direction of the bar magnet assembly 201 may also be parallel to the running direction of the mobile device. In this case, the first control module 104 may detect when the magnetic field signal strength detected by the magnetic detection element meets the third preset threshold The self-mobile device is controlled to reduce the running speed, and when it is detected that the magnetic field signal strength meets the fourth preset threshold, the self-mobile device is controlled to stop running. Similarly, the third preset threshold and the fourth preset threshold may be determined according to the number of magnet assemblies installed in each group and the position of the wireless charging transmitter module 202, which is not limited in the present disclosure. That is to say, the embodiments of the present disclosure can accurately locate the wireless charging transmitting module 202 of the wireless charging station according to the change of the magnetic field signal strength of the provided magnet assembly. Similarly, the embodiments of the present disclosure can accurately locate the wireless charging transmitter module 202 of the wireless charging station according to the change in the magnetic field signal strength of the magnet assembly.

In other embodiments of the present disclosure, the in-position guidance device 201 may further include a wireless signal transmission component, and the in-position sensing module 103 may include a wireless signal reception component, or the in-position guidance device 201 may include a wireless signal reception component, and in-position sensing The measurement module 103 may include a wireless transmission component. The wireless signal transmitting component can transmit a wireless signal, while the wireless signal receiving component can receive the discovery signal transmitted by the wireless signal transmitting component, and the wireless signal in the embodiment of the present disclosure can be transmitted within a preset distance. Wherein, the wireless signal transmitting component may include an RFID (radio frequency) transmitter, and the corresponding wireless signal receiving component includes an RFID reader.

In a possible implementation manner, the in-position guidance device 201 is an RFID transmitter, and the in-position sensing module 103 is an RFID reader. When the RFID reader detects the radio frequency signal transmitted by the RFID transmitter, the first signal is sent to the first control module , Indicating that a guiding device in place has been detected. The corresponding first control module performs the speed-down adjustment of the self-mobile device or controls the self-mobile device to stop running when the first signal is received.

In another possible implementation manner, the in-place guidance device 201 may be an RFID reader, the in-place sensing module 103 may be an RFID transmitter, and a communication module that transmits signals between the wireless charging station and the mobile device, the RFID reader When the device detects the radio frequency signal emitted by the RFID transmitter, and the mobile device receives the communication signal transmitted by the wireless charging station, the first control module 104 may determine that the in-place guidance device is detected, and at this time perform the speed-down adjustment from the mobile device Or control the mobile device to stop running.

In addition, in some other embodiments of the present disclosure, the in-place guidance device 201 of the wireless charging station 200 may include a wireless charging transmitting module 202, that is, the wireless charging transmitting module 202 may be used to provide charging power, and may also be used to locate an inductor. Since the wireless charging transmitting module 202 includes a charging coil, the corresponding in-place sensing module 103 may include a coil induction module for sensing the charging coil. Due to the influence of the magnetic field of the charging coil, the equivalent impedance of the metal, coil, magnet and other devices close to the charging coil will change. At this time, the in-position guidance device 201 can be determined and detected according to the change of the equivalent impedance. Using a wireless charging transmitter module as a guiding device in place not only increases the reliability of the detection system, but also reduces costs.

7 shows a schematic diagram of detecting a wireless charging transmitting module from a coil induction module of a mobile device according to an embodiment of the present disclosure. As shown in FIG. 7, the coil induction module 103 is composed of a PCB on-board coil, a capacitor, and an Inductance to Digital Converter (referred to as "detection IC"). The coil induction module 103 can detect the wireless charging and transmitting module 202, that is, detects the guiding device in place 201. FIG. 8 shows another schematic diagram of detecting a wireless charging transmitting module from a coil induction module of a mobile device according to an embodiment of the present disclosure. As shown in FIG. 8, the coil induction module 103 in the self-mobile device 100 in the embodiment of the present disclosure may be a metal detection module 103, and the metal detection module 103 may be in proximity to the coil in the in-place guidance device 201 including the wireless charging transmitting module The impedance changes when the device is waiting. Therefore, the first control module 104 can determine whether the wireless charging transmitter module 202 is detected according to the output equivalent impedance of the metal detection module 103. The first control module 104 is connected to the metal detection module 103 to obtain the equivalent impedance output by the metal detection module. When the equivalent impedance output by the metal detection module 103 changes to a preset range, it is determined that the wireless charging transmitter module 202 is detected . Wherein, the preset range may indicate that the distance between the metal detection module 103 and the wireless charging transmitter module 202 reaches the distance requirement at this time, and it may be determined that the in-place guidance device is detected at this time, therefore, the embodiment of the present disclosure does not perform the value of the preset range Limited, can be set according to different needs.

FIG. 9 shows a schematic diagram of the process of returning docking from the mobile device to the wireless charging station. FIG. 10 is a schematic diagram of FIG. 9 in another direction. As shown in FIGS. 9-10, in the embodiment of the present disclosure, when the metal detection module 103 is directly above the wireless charging transmitter module 202, the equivalent impedance output by the metal detection module 103 is the smallest, and when the metal detection module 103 outputs When the equivalent impedance is within a certain preset range (detected and set in advance), it can be determined that the metal detection module 103 is above the wireless charging transmitter module 202. At this time, the first control module 104 can control the self-mobile device 100 to decelerate to walk for a period of time to ensure that the wireless charging receiving module 101 on the self-mobile device 100 is directly above the wireless charging transmitting module sending module 202, and then it can stand by for charging.

In addition, the coil induction module 103 in the embodiment of the present disclosure may also include an LC oscillator, and the first control module 104 may be connected to the LC oscillator to obtain the equivalent impedance of the LC oscillator. And the first control module 104 may determine that the in-place guidance device is detected when the equivalent impedance output by the LC oscillator changes to a preset range. The preset range may indicate that the distance between the LC oscillator and the wireless charging transmitter module 201 meets the distance requirement at this time, and it may be determined that the in-place guidance device is detected at this time, so the value of the preset range is not limited in this embodiment of the present disclosure , Can be set according to different needs.

In the embodiments of the present disclosure, the LC oscillator may include at least one of the following structures:

FIG. 11 shows a schematic diagram of the composition structure of an LC oscillator according to an embodiment of the present disclosure. As shown in FIG. 9, the LC oscillator may include a first inductor L1, a first capacitor C1, a first resistor R1 and a The first oscillator LC1.

FIG. 12 shows another schematic structural diagram of an LC oscillator according to an embodiment of the present disclosure. As shown in FIG. 12, the LC oscillator may include a second inductor L2 and a second oscillator LC2 connected in parallel.

FIG. 13 shows another schematic structural diagram of an LC oscillator according to an embodiment of the present disclosure. As shown in FIG. 13, the LC oscillator may include a first coil S1 and a first circuit coupled to the first coil S1 The first circuit includes a third inductor L3, a second resistor R3 and a third oscillator LC3 connected in series, wherein the first coil S1 is coupled to the third inductor L3.

14 is a schematic diagram of another composition structure of an LC oscillator according to an embodiment of the present disclosure, wherein, as shown in FIG. 14, the LC oscillator may include a fourth inductor L4 and a third resistor R3 connected in series, and connected in parallel The second capacitor C2 and the third oscillator LC3 on both sides of the fourth inductor L4 and the third resistor R3.

Based on the above-mentioned LC oscillator, it is possible to determine whether the LC oscillator is close to the wireless charging transmitter module 202 by detecting the change of the equivalent impedance output by the LC oscillator. In the embodiment of the present disclosure, when the wireless charging transmitter module 202 is closer, The smaller the equivalent impedance of the output of the LC oscillator, and the minimum equivalent impedance when the LC oscillator is located directly above the wireless charging transmitting module 202.

Alternatively, in the embodiment of the present disclosure, the in-place sensing module 103 may also be a coil assembly, the coil assembly may generate an impedance change according to the signal transmitted by the wireless charging transmitting module 202, and the first control module may change to a preset according to the impedance In the range, it is determined that the in-position guidance device 201 is sensed.

In addition, FIG. 15 shows another schematic structural diagram of the in-place guidance device 201 of the wireless charging station according to an embodiment of the present disclosure. Wherein, the in-position guidance device 201 in the embodiment of the present disclosure may further include an auxiliary coil assembly, the auxiliary coil assembly includes the guidance assembly 2011 and the in-position assembly 2012, and the in-position sensing module 103 includes a guidance assembly detection unit and a detection unit for detecting the guidance assembly The in-place component detection unit of the in-place component (not shown in the figure). Among them, the embodiment of the present disclosure may first further guide the movement from the mobile device to the wireless charging transmitting module of the wireless charging station through the guiding component 2011, for example, the first control module 104 passes the stored second location information of the wireless charging station and the obtained During the process of controlling the movement from the mobile device to the wireless charging station by the first position information of the mobile device, the guide component 2011 may be further sensed by the guide component detection unit. The design of the guide component 2011 may be the same as the principle of the guide line 109, namely The guide assembly 2011 may be a guide wire (may be configured as a coil) located in a part of the charging base 203 of the wireless charging station 200, so the guide assembly detection unit may sense the magnetic signal of the guide assembly 109, and the first control module 104 may detect The received magnetic force signal controls the movement from the mobile device 100 to the wireless charging station 200, wherein the principle of the first control module 104 controlling the self-mobile device according to the received magnetic force signal is the same as the description in the above embodiment, and will not be repeated here.

In addition, the in-place component 2022 may include a sensor component that interacts with the self-mobile device 100 or a mechanical structure component that abruptly changes the movement state of the self-mobile device 100. The sensor component may include the wireless signal transmitter / receiver in the above embodiment, for example, an RFID transmitter / receiver, a magnetic component, such as a magnetic strip or magnetic steel, etc. The in-place component detection unit controls the self-control based on the detected signal. The mobile device stopped working. The mechanical structure component may be a structure that protrudes or is recessed on the charging base 203, and may stop the self-mobile device from moving when the self-mobile device moves onto the charging base, and at this time, the wireless charging receiving module of the self-mobile device may be located in the wireless Directly above the charging transmitter module. The in-place component detection unit can detect the magnetic force signal, and the first control module can control the self-mobile device to stop running when the magnetic force signal does satisfy the first preset condition.

In addition, FIG. 16 shows another structural schematic diagram of the in-place guidance device 201 of the wireless charging station according to an embodiment of the present disclosure. Wherein, the in-position guiding device 201 includes a ring assembly. The ring assembly may include an outer ring assembly 2013 and an inner ring assembly 2014. The inner ring assembly 2014 is provided with a wireless charging transmitter module 202, and the outer ring assembly 2013 is located outside the inner ring assembly 2014. The in-place sensing module 103 may include an outer ring detection unit that detects the outer ring component and an inner ring detection unit that detects the inner ring component. The first control module 104 may be configured to adjust the posture of the self-mobile device based on the signal detected by the outer loop detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and control the self-mobile device based on the signal detected by the inner loop detection unit Stop running.

That is to say, in the embodiment of the present disclosure, the wireless charging transmitting module 202 of the wireless charging station 200 can be disposed in the ring assembly, the in-position sensing module 103 can sense the ring assembly and the first control module can sense the in-position sensing module 103 The measured information controls to move to the wireless charging transmitting module 202 for charging.

The outer ring detection unit in the in-position sensing module 103 may include a first outer ring detection unit and a second outer ring detection unit, and the first control module is configured to compare the signal detected by the first outer ring detection unit with the second outer ring detection unit The signal detected by the ring detection unit controls the mobile device to enter the outer ring assembly based on the coincidence of the detected signals. Wherein, the first outer ring detection unit and the second outer ring detection unit can be located in the base of the mobile device and are symmetrically arranged on both sides of the base. When the intensity of the signal detected by the first outer ring detection unit and the second When the signal strength detected by the outer ring detection unit is the same, it indicates that the current moving direction is the direction of the center of the outer ring component. At this time, the first control module 104 can control the mobile device to move in the current direction and enter the outer ring component 2013 . In addition, the outer ring assembly 2013 in the embodiment of the present disclosure may include an outer ring coil and a signal generator for generating an electrical signal, the outer ring coil transmits current to form a magnetic signal, and the first control module is configured to When the phase or intensity of the magnetic signal of the outer ring coil detected by the detection unit is consistent with the phase or intensity of the magnetic signal of the outer ring coil detected by the second outer ring detection unit, the mobile device is controlled to enter the outer ring coil, Make the mobile device move toward the center of the wireless transmission module, and finally prepare to dock with the wireless transmission module

In addition, in the embodiments of the present disclosure, different signals can be transmitted on the outer ring assembly 2013 and the inner ring assembly 2014. For example, both the outer ring assembly 2013 and the inner ring assembly 2014 can be configured as coils, and both can be connected to a signal generator. And receive different signals, so that the outer ring component 2013 and the inner ring component 2014 can transmit different signal parameters, for example, two types of electrical signals of different types or the same electrical signals of different frequencies. Therefore, the inner ring component detection unit of the in-place sensing module can send a second signal to the first control module when it detects a magnetic signal matching the inner ring component, at which time the first control module can control the self-mobile device to decelerate to run Or stop running. It can be understood that the inner ring component detection unit may also include two inner ring component detection units, and the posture of the mobile device is further adjusted according to the strength and / or phase of the signals detected by the two inner ring component detection units, so that they are directed toward the wireless The center of the circle of the charging and transmitting module 202 moves.

In addition, the inner ring assembly 2014 may also include a magnetic stripe, and the corresponding inner ring assembly detection unit may also include a magnetic detection unit, so that when the magnetic detection unit detects a magnetic force value that matches the magnetic stripe, it sends to the first control module The second signal, at this time, the second control module may control the self-mobile device to decelerate or stop running.

Based on the above configuration of the embodiment of the present disclosure, the movement from the mobile device to the wireless charging station can be achieved in various ways, and the positioning of the wireless charging transmitter module can be further accurately determined by the in-situ guidance device, so that the charging from the mobile device is conveniently achieved.

In addition, in the embodiment of the present disclosure, the first control module 104 can also control the wireless charging receiving module to receive the wireless charging signal sent by the wireless charging station when the mobile device 100 enters the coverage corresponding to the predetermined charging position, that is, the charging operation can be performed . In the process of moving from the mobile device 100 to the wireless charging station, it can be determined whether the mobile device has entered the coverage range corresponding to the predetermined charging location, wherein the mobile device can be determined to have entered Coverage range corresponding to preset charging position:

a) Based on the first position information of the mobile device and the second position information of the wireless charging station, determine whether the distance between the two is less than the preset distance, and if so, determine that the coverage range corresponding to the preset charging position is entered;

b) Detecting whether the first communication module of the mobile device establishes a wireless connection with the second communication module of the wireless charging station, and if so, it is determined to enter the coverage range corresponding to the preset charging position;

c) Detect whether the first communication module from the mobile device establishes a wireless connection with the second communication module of the wireless charging station, and whether the signal strength of the wireless connection reaches a preset signal strength, if the first communication module and the second communication module are established Wireless connection, and the signal strength reaches the preset signal strength, it is determined to enter the coverage range corresponding to the preset charging position.

In summary, the embodiments of the present disclosure can conveniently achieve the return guidance from the mobile device and the precise positioning of the wireless charging transmitting module of the wireless charging station.

It can be understood that the above-mentioned embodiments mentioned in the present disclosure can be combined with each other to form a combined embodiment without violating the principle logic, which is limited to space and will not be repeated in this disclosure.

In addition, the present disclosure also provides a wireless charging station, an automatic working system, and a charging method thereof. The above technical solutions and descriptions can be found in the corresponding records from the embodiments of the mobile device, and are not repeated here.

In addition, an embodiment of the present disclosure also provides a wireless charging station. FIG. 17 shows a block diagram of a wireless charging station according to an embodiment of the present disclosure, where the wireless charging station 200 can be used to charge a mobile device, and the wireless charging station 200 can include:

The first power module 204, which is used to provide power to the wireless charging station;

The wireless charging transmitting module 202 is arranged in the charging area and is configured to transmit a wireless charging signal to the self-mobile device through the power provided by the first power module to charge the self-mobile device;

The wireless charging station is used in conjunction with a guidance device configured to generate guidance information for guiding movement from the mobile device to the wireless charging station;

The in-place guidance device 201 is configured for the self-mobile device to sense the in-place guidance device to determine the position of the wireless charging station, and adjusts the operating parameters and operating parameters of the self-mobile device when the in-place guidance device is sensed from the mobile device Including: running speed and / or running direction;

The second control module 205 is configured to control the wireless charging transmitting module to send a wireless charging signal to charge the mobile device.

The guidance device may be the guidance line 109 of the above embodiment, and the wireless charging station may provide a power signal for the guidance line laid out from the boundary of the working area of the mobile device. Based on the power signal, guidance information (such as a magnetic force signal) may be generated, thereby The mobile device can detect the movement information to move to the wireless charging station.

In addition, the guidance device may also include a position sending device that can send the second position information of the wireless charging station, so that the second position information is received from the mobile device and moved to the wireless charging station.

In addition, the in-place guidance device may also include a magnet assembly for the self-moving device to determine that the in-place guidance device is detected when the magnetic field signal of the magnet assembly meets the first predetermined condition.

In a possible implementation manner, the magnet assembly includes a bar magnet assembly, and the bar magnet assembly includes a magnetic bar or a bar magnet assembly formed by arranging magnetic objects. Moreover, when the installation direction of the bar magnet assembly is perpendicular to the running direction of the self-moving device, in one embodiment, the bar magnet assembly includes at least two groups for the self-mobile device to detect the first group of bar magnet assembly When the strength of the magnetic field signal reaches the first preset threshold, the self-moving device is controlled to decrease the operating speed, and when it is detected that the strength of the magnetic field signal of the second group of bar magnet assemblies meets the second preset threshold, the self-mobile device is controlled to stop running. Or, when the installation direction of the bar magnet assembly is parallel to the running direction of the self-moving device, the self-moving device controls the self-moving device to reduce the running speed when detecting that the magnetic field signal strength of the bar magnet assembly meets the third preset threshold, and detects the magnetic field signal When the intensity meets the fourth preset threshold, the self-mobile device is controlled to stop running.

In a possible implementation manner, the in-position guidance device includes a wireless signal transmission component, and the self-mobile device includes an in-position sensing module, the in-position sensing module includes a wireless signal reception component, or the in-position guidance device includes a wireless signal reception component, in-position sensing The module includes a wireless transmitting component; a wireless signal transmitting component is used for the mobile device to determine that the in-place guidance device is detected after the wireless signal receiving component detects the wireless signal generated by the wireless signal transmitting component. The wireless signal transmitting component includes an RFID transmitter, and the wireless signal receiving component includes an RFID reader.

In a possible implementation manner, the in-position guidance device is an RFID transmitter, and the in-position sensing module is an RFID reader. When the RFID reader detects the radio frequency signal emitted by the RFID transmitter, it is determined that the in-position guidance device is detected.

In a possible implementation manner, the in-place guidance device is an RFID reader, the in-place sensing module is an RFID transmitter, and a communication module for transmitting signals is also included between the wireless charging station and the mobile device, and the RFID reader detects the RFID transmission When the radio frequency signal transmitted by the device and the communication signal transmitted from the wireless charging station are received from the mobile device, it is determined that the guiding device is detected in place.

The in-place guidance device includes a wireless charging transmitting module, and the self-moving device includes a coil induction module; when the equivalent impedance output by the coil induction module changes to a preset range, the self-mobile device determines that the in-place guidance device is detected.

In a possible implementation manner, the coil induction module is a metal detection module, and the equivalent impedance output by the metal detection module is obtained from the mobile device.

In a possible implementation manner, the coil induction module includes an LC oscillator, and the equivalent impedance of the LC oscillator is obtained from the mobile device.

In a possible implementation manner, the LC oscillator includes at least one of the following structures:

A first inductor, a first capacitor, a first resistor and a first oscillator connected in parallel;

A second inductor and a second oscillator connected in parallel;

A first coil and a first circuit coupled to the first coil, the first circuit includes a third inductor, a second resistor, and a third oscillator connected in series, wherein the first coil is coupled to the third inductor;

A fourth inductor and a third resistor connected in series, and a second capacitor and a third oscillator connected in parallel on both sides of the fourth inductor and the third resistor.

In a possible implementation manner, the guidance apparatus includes a positioning module, and the self-mobile device is connected to a positioning module. The self-mobile device uses the second location information of the wireless charging station as guidance information, and uses the positioning module to locate the first The location information and the second location information control the autonomous mobile device to move toward the wireless charging station, and the second location information of the wireless charging station includes the pre-stored location of the wireless charging station.

In a possible implementation manner, the in-position guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guidance assembly and an in-position assembly, and the self-moving device includes a guidance assembly detection unit that detects the guidance assembly and an in-position assembly detection unit that detects the in-position assembly;

The self-moving device guides the self-mobile device to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and controls the self-mobile device to stop running based on the signal detected by the in-place component detection unit.

In a possible implementation manner, the guide assembly includes a coil assembly, and the self-moving device guides the self-mobile device to move along the coil assembly to the wireless charging transmitting module based on the magnetic force signal detected by the guide assembly detection unit.

In a possible implementation manner, the in-place component includes a sensor component that interacts with the self-moving device or a mechanical structure component capable of abruptly changing the motion state of the self-moving device.

In a possible implementation manner, the in-place guidance device includes a ring assembly. The ring assembly includes an outer ring assembly and an inner ring assembly. The inner ring assembly is provided with a wireless charging and transmitting module. Since the mobile device includes an outer ring detection that detects the outer ring assembly Unit and inner ring detection unit for detecting inner ring components;

The self-mobile device adjusts the posture of the self-mobile device based on the signal detected by the outer ring detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and controls the self-mobile device to stop running based on the signal detected by the inner ring detection unit.

In a possible implementation manner, the outer ring detection unit includes a first outer ring detection unit and a second outer ring detection unit, and the first control module is configured to compare the signal detected by the first outer ring detection unit with the second outer ring The signals detected by the detection unit are controlled to enter the outer ring assembly from the mobile device based on the coincidence of the detected signals.

In a possible implementation manner, the outer ring assembly includes an outer ring coil and a signal generator for generating a point signal, the outer ring coil transmits current to form a magnetic signal, and the first control module is configured to detect the first outer ring When the phase or intensity of the magnetic signal of the outer ring coil detected by the unit coincides with the phase intensity of the magnetic signal of the outer ring coil detected by the second outer ring detection unit, the mobile device is controlled to enter the outer ring coil.

In a possible implementation manner, the signal parameters transmitted by the inner ring component and the outer ring component are different.

In a possible implementation manner, the inner ring assembly includes a magnetic stripe, and the inner ring detection unit includes a magnetic detection element.

In a possible implementation manner, the wireless charging and transmitting module includes a resonant coil assembly.

In a possible implementation manner, the charging base of the wireless charging station is constructed as a hollow bottom plate.

In a possible implementation manner, when the mobile device enters the coverage range corresponding to the predetermined charging position, the second control module is configured to control the wireless charging transmitting module to send a wireless charging signal to charge the mobile device.

In a possible implementation manner, the wireless charging station includes a second communication module, and the mobile device includes the first communication module;

Detecting whether a wireless connection is established between the second communication module and the first communication module;

If the second communication module successfully establishes a wireless connection with the first communication module, it is determined that the mobile device enters the coverage range corresponding to the predetermined charging location.

In a possible implementation manner, the wireless charging station includes a second communication module, and the mobile device includes the first communication module;

Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine that the mobile device enters the coverage area corresponding to the predetermined charging location.

18 shows a block diagram of a wireless charging station according to an embodiment of the present disclosure, where, as shown in FIG. 18, the wireless charging station may be used to charge a self-mobile device, and may include:

The first power module 204, which is used to provide power to the wireless charging station;

The wireless charging transmitting module 202 is configured to transmit a wireless charging signal to the self-mobile device through the power provided by the first power module to charge the self-mobile device;

The wireless charging station 200 is used in conjunction with a guidance device, and the guidance device is configured to generate guidance information for guiding movement from the mobile device to the wireless charging station;

A guiding device 201 in place, which includes a ring assembly including an outer ring assembly 2013 and an inner ring assembly 2014 disposed inside the outer ring assembly, a wireless charging transmitter module is located in the inner ring assembly, and the mobile device is based on the sensed outer ring The signal of the component adjusts the posture of the self-mobile device to guide the self-mobile device to move toward the wireless charging transmitter module, and controls the self-mobile device to reduce the running speed or stop running based on the sensed signal of the inner ring component;

The second control module 205 is configured to control the wireless charging transmitting module to send a wireless charging signal to charge the mobile device.

An embodiment of the present disclosure also provides an automatic working system. The automatic working system includes the self-mobile device 100 and the wireless charging station 200 in the above embodiments. For the corresponding technical solutions and descriptions above, reference may be made to the embodiments of the self-mobile device and the wireless charging station. The corresponding records will not be repeated here.

19 shows a flowchart of a wireless charging method of an automatic working system according to an embodiment of the present disclosure, where the automatic working system includes the mobile device 100 and the wireless charging station 200 in the above-described embodiment, and the wireless charging station 200 The guidance device for generating the guidance signal is used in conjunction, and the wireless charging station 100 is provided with a guidance device in place, and the method includes:

S10: Detect the pilot signal;

S20: When the guidance signal is detected, control the mobile device to move toward the wireless charging station;

S30: sensing the in-place guidance device set on the wireless charging station;

S40: Adjust the operating parameters of the self-moving device when the in-place guidance device is sensed. The operating parameters include: operating speed and / or operating direction.

S50: Control the wireless charging station to transmit a wireless charging signal to charge the mobile device.

In a possible implementation manner, the in-place guide device includes a magnet assembly, and sensing the in-place guide device provided on the wireless charging station includes:

Detect the magnetic field signal of the magnet assembly through the magnetic detection element;

When the magnetic detection element detects that the magnetic field signal of the magnet assembly meets the first preset condition, it is determined that the in-position guiding device is detected.

In a possible implementation manner, the in-place guidance device includes a wireless signal transmission component, and sensing the in-position guidance device provided on the wireless charging station includes:

When the wireless signal generated by the wireless signal transmitting component is detected by the wireless signal receiving component, it is determined that the in-position guidance device is detected.

In a possible implementation manner, the in-place guidance device includes a wireless signal receiving component, and sensing the in-position guidance device provided on the wireless charging station includes:

When the wireless signal generated by the wireless signal transmitting component is detected by the wireless signal receiving component, it is determined that the in-position guidance device is detected.

In a possible implementation manner, the in-place guidance device includes a wireless charging transmitting module, and sensing the in-place guidance device provided on the wireless charging station includes:

When the equivalent impedance output by the coil induction module changes to a preset range, it is determined that the guiding device is detected in place.

In a possible implementation manner, the in-position guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guidance assembly and an in-position assembly, and the in-position guidance device provided on the sensing wireless charging station includes:

The self-mobile device is guided to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and the self-mobile device is controlled to stop running based on the signal detected by the in-place component detection unit.

In a possible implementation manner, the in-position guidance device includes a ring assembly. The ring assembly includes an outer ring assembly and an inner ring assembly. The inner ring assembly is provided with a wireless charging transmitter module and senses the in-place guidance device provided on the wireless charging station include:

The posture of the self-mobile device is adjusted based on the signal detected by the outer loop detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and the self-mobile device is controlled to stop running based on the signal detected by the inner loop detection unit.

In a possible implementation manner, the method further includes:

When the mobile device enters the coverage area corresponding to the predetermined charging position, the wireless charging signal sent by the wireless charging station is received through the wireless charging receiving module.

20 shows another flowchart of a wireless charging method of an automatic working system according to an embodiment of the present disclosure, where the automatic working system includes a self-mobile device and a wireless charging station, and the wireless charging station cooperates with a guiding device for generating a guiding signal To use, the wireless charging station is equipped with a guiding device in place, the method includes:

S100: detect the pilot signal;

S200: When the guidance signal is detected, control the mobile device to move toward the wireless charging station;

S300: Sensing the in-place guidance device provided on the wireless charging station, wherein the in-place guidance device includes a ring assembly, the ring assembly includes an outer ring assembly and an inner ring assembly disposed inside the outer ring assembly, and the wireless transmission module is located in the inner ring assembly;

S400: Adjust the attitude of the self-mobile device based on the sensed signal of the outer ring component to guide the self-mobile device to move toward the wireless transmission module, and control the self-mobile device to reduce the running speed or stop based on the sensed signal of the inner ring component run;

S500: Control the wireless charging station to transmit a wireless charging signal to charge the mobile device.

In addition, in the prior art, in order to realize the fast and convenient charging operation between the wireless charging station and the mobile device, the wireless charging station establishes the electrical connection between the power supply module and the wireless charging transmitter module in real time, and the mobile device The wireless charging receiving module is activated in real time to ensure that the wireless charging signal can be received to perform charging, but due to maintaining the activated state of the wireless charging transmitting module or the wireless charging receiving module, a large amount of power is consumed, which does not meet the requirements of energy saving.

21 shows a block diagram of a mobile device according to an embodiment of the present disclosure. The mobile device 100 can only start the wireless charging receiving module to receive the wireless charging signal to perform the charging operation when it moves to the coverage corresponding to the predetermined charging position, and does not need to start the wireless charging receiving module in real time, which effectively reduces power consumption.

As shown in FIG. 21, the self-mobile device according to an embodiment of the present disclosure may include:

The wireless charging receiving module 101 is configured to perform a charging operation based on the wireless charging signal received from the wireless charging station;

The first control module 104 is configured to receive the wireless charging signal sent by the wireless charging station through the wireless charging receiving module when the mobile device enters the coverage corresponding to the predetermined charging position.

The first control module 104 can determine whether the mobile device has entered the coverage range corresponding to the predetermined charging position, wherein the first control module 104 can determine that the mobile device has entered the preset charging position by at least one of the following ways Of coverage:

a) Since the mobile device includes a first communication module, the wireless charging station includes a second communication module;

Based on the first position information from the mobile device and the second position information of the wireless charging station, it is determined whether the distance between the two is less than the preset distance, and if so, it is determined to enter the coverage range corresponding to the preset charging position; The distance can be set to 0.1 m, or 0.5 m, or other distance values. Those skilled in the art can set it according to requirements, which is not specifically limited in the embodiments of the present disclosure.

b) The self-mobile device includes a first communication module, and the wireless charging station includes a second communication module; detecting whether the first communication module of the self-mobile device establishes a wireless connection with the second communication module of the wireless charging station; Set the coverage area corresponding to the charging position.

A communication connection can be established between the self-mobile device and the wireless charging station in the embodiments of the present disclosure, for example, the first communication module of the self-mobile device can send pairing information to the outside, and the second communication module of the wireless charging station can receive the pairing information, where , The pairing information includes the identification from the mobile device. The second control module of the wireless charging station can verify the pairing information, and if the verification is passed, return the verification passed information and establish a wireless connection with the first communication module. The first communication module and the second communication module may be matching Bluetooth modules, WIFI modules, etc. When verifying the pairing information, you can query whether the self-mobile charging identifier matching the wireless charging station is stored, and if so, verify by.

Alternatively, in some other embodiments, the wireless charging station may send pairing information to the outside through the second communication module, and the first communication module from the mobile device may receive the pairing information, where the pairing information includes the identification of the wireless charging station . The first communication module from the mobile device can verify the pairing information, and if the verification is passed, return the verification passed information and establish a wireless connection with the second communication module. When verifying the pairing information, you can query whether the identification of the wireless charging station that matches the mobile device is stored, and if so, the verification is passed.

Based on the above embodiments, the embodiments of the present disclosure may determine that the mobile device has entered the coverage range corresponding to the preset charging position when the first communication module and the second communication module establish a communication connection.

c) Detect whether the first communication module from the mobile device establishes a wireless connection with the second communication module of the wireless charging station, and whether the signal strength of the wireless connection reaches a preset signal strength, if the first communication module and the second communication module are established Wireless connection, and the signal strength reaches the preset signal strength, it is determined to enter the coverage range corresponding to the preset charging position.

The manner in which the first communication module and the second communication module establish the communication connection may be as in the embodiment of mode b), and details are not repeated here. When it is determined that the first communication module and the second communication module establish a wireless connection, it is also necessary to detect whether the signal strength of the wireless connection reaches a preset signal strength, which may be performed according to the type of the communication module or different requirements The setting is not specifically limited in this disclosure. In the process of moving from the mobile device to the wireless charging station, if the two establish a connection, the closer the distance between the mobile device and the wireless charging station, the stronger the signal strength, so the signal strength can reach the preset signal strength When it is determined that the mobile device enters the coverage range corresponding to the predetermined charging location.

In other embodiments of the present disclosure, it may also be determined in other ways whether the self-mobile device enters the coverage range corresponding to the predetermined charging position, for example, the self-mobile device may sense the When the guidance module 201 is in place, it is determined to enter the coverage corresponding to the predetermined charging position. That is, as long as the coverage range from the mobile device entering the predetermined charging position can be determined, it can be used as an embodiment of the present disclosure.

In the embodiment of the present disclosure, after the mobile device determines to enter the coverage area of the predetermined charging location, it can also request charging from the wireless charging station to determine the charging operation performed by the wireless charging receiving module.

FIG. 22 shows another module diagram of the self-mobile device according to an embodiment of the present disclosure, wherein the first communication module of the self-mobile device may further include a first request module 110, and the first request module 110 generates a request signal and sends a wireless signal to the wireless device. The charging station sends a request signal; after the wireless charging station receives the request signal, the wireless charging station charges the mobile device.

That is, in the embodiment of the present disclosure, since the mobile device 100 may enter the coverage of the predetermined charging position, the first request module 110 may send a request signal to the wireless charging station to request charging, and the second communication module of the wireless charging station 200 After receiving the request signal, the second communication module will switch to the normally open mode and send a response signal to the mobile device to indicate that charging is possible. At the same time, the wireless charging station activates the transmitting coil of the wireless charging transmitting module, the wireless charging station Ready to charge. After receiving the response signal from the first communication module of the mobile device, it performs an accurate docking operation.

In a specific embodiment, after the mobile device receives the response signal, the first control module reduces its operating speed from the mobile device and moves to a predetermined charging position.

In addition, in the embodiment of the present disclosure, the wireless charging station may also ask the mobile device whether to charge, and then perform the charging operation after receiving the response.

As shown in FIG. 23, the self-mobile device may further include a response module 111, the wireless charging station sends a request signal to the self-mobile device, the response module returns a response signal according to the request signal sent by the wireless charging station; and, the response is received at the wireless charging station After the response signal matched by the module and the request signal, the wireless charging station charges the mobile device.

Wherein, the wireless charging station may send a request signal to the mobile device when it moves from the mobile device to the coverage corresponding to the predetermined charging position, or periodically send the request signal at a preset time interval, or it may The request signal is sent when the mobile device establishes a wireless connection, which is not limited in the embodiments of the present disclosure. Wherein, the request signal may include an identifier of the wireless charging station to help the mobile device verify the request signal.

When the mobile device receives the request signal sent by the wireless charging station through the first communication module, it may return a response signal for performing the charging operation based on the request signal, and the response signal may also include the identification of the mobile device. In addition, the mobile device can also return a response signal to perform the charging operation after the identification of the wireless charging station's identity in the request signal is passed, to ensure that the matching charging request and response between the mobile device and the wireless charging station are not Effects of other signals.

In addition, in the embodiment of the present disclosure, the first control module may control the self-mobile device to decrease the running speed and move to the predetermined charging position after determining that the self-mobile device enters the coverage corresponding to the predetermined charging position.

In addition, in the embodiment of the present disclosure, after the mobile device enters the coverage range corresponding to the predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module. After entering the coverage range corresponding to the predetermined charging position, the mobile device can send an in-position signal to the wireless charging station. At this time, the wireless charging station can turn on the wireless charging transmitter module to perform the charging operation.

In addition, in the embodiment of the present disclosure, the self-mobile device further includes a detection module 105 (as shown in FIG. 3). During the charging process, the detection module detects whether charging of the self-mobile device is completed, and if the charging is completed, controls wireless charging The station enters low power mode. The detection module 105 may be electrically connected to the power module 106 of the mobile device to detect the power of the power module. When the power of the power module meets the predetermined power, for example, when the total capacity of the power supply is reached, the charging of the mobile device is determined carry out. At this time, the first control module may send a charging completion message to the wireless charging station through the first communication module. After the second communication module of the wireless charging station receives the charging completion message, the second control module controls the wireless charging station to enter a low power consumption state . Understandably, in the low power consumption state, the wireless charging station only maintains the wireless communication function.

Based on the above configuration, it is possible to perform the startup of the wireless charging receiving device in the case of moving from the mobile device to the coverage corresponding to the predetermined charging position, thereby performing the charging operation using the wireless charging station.

FIG. 24 shows a block diagram of a wireless charging station according to an embodiment of the present disclosure. As shown in FIG. 24, the wireless charging station may include:

The first power module 204, which is used to provide power to the wireless charging station;

The wireless charging transmitting module 202 is configured to transmit a wireless charging signal to the self-mobile device through the power provided by the power module to charge the self-mobile device;

The second control module 205 is configured to switch on the first power supply module and the wireless charging transmitting module when the self-mobile device enters the coverage corresponding to the predetermined charging position to start the wireless charging transmitting module to transmit the wireless charging signal to the self-mobile device.

Among them, the embodiments of the present disclosure can realize that the wireless charging transmission module is activated only when the mobile device moves to the coverage corresponding to the predetermined charging position, so that it is necessary to maintain the startup state of the wireless charging transmission module, which can effectively reduce power consumption.

Similarly, in a possible implementation manner, the wireless charging station includes a second communication module, and the mobile device includes the first communication module;

Wherein, it is detected whether a wireless connection is established between the second communication module and the first communication module; if the second communication module and the first communication module successfully establish a wireless connection, it is determined that the mobile device enters the coverage range corresponding to the predetermined charging location.

Wherein, the second control module 205 may determine whether the distance between the two is less than the preset distance based on the first location information of the mobile device and the second location information of the wireless charging station, and if so, determine that the mobile device Set the coverage area corresponding to the charging position; wherein, the preset distance may be 0.1m, or 0.5m, or may be other distance values, which can be set by those skilled in the art according to requirements, and this embodiment of the present disclosure does not specifically limit this . Wherein, the self-mobile charging device can send its first position information to the wireless charging station through the first communication module, so that the second control module can receive the first position information through the second communication module, and determine the self-mobile device and the wireless charging station the distance between.

In a possible implementation manner, it may also be detected whether the first communication module of the mobile device establishes a wireless connection with the second communication module of the wireless charging station, and if so, the second control module determines that the mobile device enters preset charging The coverage area corresponding to the location.

In a possible implementation manner, it can also be detected whether the first communication module from the mobile device establishes a wireless connection with the second communication module of the wireless charging station, and whether the signal strength of the wireless connection reaches a preset signal strength, if the first When a communication module establishes a wireless connection with the second communication module and the signal strength reaches the preset signal strength, the first control module may determine that the mobile device enters the coverage area corresponding to the preset charging position.

In a possible implementation manner, the wireless charging station includes a receiving module that sends a request signal from the mobile device to the wireless charging station;

After the receiving module receives the request signal, the second control module is configured to charge the wireless mobile station to the mobile device.

In a possible implementation manner, the wireless charging station includes a second request module and a receiving module, and the second request module sends a request signal to the mobile device;

After the receiving module receives the response signal matched with the request signal from the mobile device, the second control module is configured to control the wireless charging station to charge the mobile device.

In a possible implementation manner, after the mobile device enters the coverage range corresponding to the predetermined charging position, the first control module is configured to control the mobile device to decrease the running speed and move to the predetermined charging position.

In a possible implementation manner, after the mobile device enters the coverage range corresponding to the predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.

In a possible implementation manner, the wireless charging station further includes a detection module. During the charging process, the detection module detects whether the charging of the mobile device is completed. If the charging is completed, the wireless charging station is controlled to enter a low power consumption mode.

In addition, an embodiment of the present disclosure also provides an automatic working system, which includes the wireless charging station according to any one of the above embodiments and the self-mobile device according to any one of the above embodiments.

FIG. 25 shows a flowchart of a charging method of an automatic working system according to an embodiment of the present disclosure, which is applied in an automatic working system. The automatic working system includes a self-mobile device and a wireless charging station that performs a charging operation for the self-mobile device. Methods include:

S1000: Determine whether the mobile device has entered the coverage range corresponding to the predetermined charging location;

S2000: If yes, start the wireless charging transmitting module to transmit a wireless charging signal to charge the mobile device.

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module; determining whether the coverage range corresponding to the self-mobile device entering a predetermined charging location includes:

Detecting whether a wireless connection is established between the second communication module and the first communication module;

If the second communication module successfully establishes a wireless connection with the first communication module, it is determined that the mobile device enters the coverage range corresponding to the predetermined charging location:

In a possible implementation manner, the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module; determining whether the coverage range corresponding to the self-mobile device entering a predetermined charging location includes:

Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine that the mobile device enters the coverage area corresponding to the predetermined charging location.

In a possible implementation manner, the wireless charging station includes a receiving module, and the method further includes:

Send a request signal from the mobile device to the wireless charging station;

After the receiving module receives the request signal, the wireless charging station charges the mobile device.

In a possible implementation manner, the self-mobile device includes a response module, and the method further includes:

The wireless charging station sends a request signal to the mobile device, and the response module returns a response signal according to the request signal sent by the wireless charging station;

After the wireless charging station receives the response signal matched with the request signal by the response module, the wireless charging station charges the mobile device.

In a possible implementation manner, the method further includes:

After the mobile device enters the coverage area corresponding to the predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.

In a possible implementation manner, the method further includes:

During the charging process, check whether the charging of the mobile device is completed;

If the charging is completed, the wireless charging station is controlled to enter a low power consumption mode.

In summary, in the embodiments of the present disclosure, the return guide device and the in-place guide device can be used to realize the return from the mobile device to the wireless charging station according to the guide information, and can accurately guide the positioning to the wireless charging transmitter module. Has the effect of precise positioning. In addition, the embodiments of the present disclosure can also start the wireless charging receiving module or the wireless charging transmitting module when the mobile device enters the coverage corresponding to the charging position, thereby effectively reducing the power consumption of the wireless charging station or the mobile device.

Those skilled in the art can understand that in the above method of the specific embodiment, the order in which the steps are written does not imply a strict execution order and constitutes any limitation on the implementation process. The specific execution order of each step should be based on its function and possible The internal logic is determined.

The present disclosure may be a system, method, and / or computer program product. The computer program product may include a computer-readable storage medium loaded with computer-readable program instructions for causing the processor to implement various aspects of the present disclosure.

The computer-readable storage medium may be a tangible device that can hold and store instructions used by the instruction execution device. The computer-readable storage medium may be, for example, but not limited to, an electrical storage device, a magnetic storage device, an optical storage device, an electromagnetic storage device, a semiconductor storage device, or any suitable combination of the foregoing. More specific examples of computer-readable storage media (non-exhaustive list) include: portable computer disks, hard disks, random access memory (RAM), read only memory (ROM), and erasable programmable read only memory (EPROM (Or flash memory), static random access memory (SRAM), portable compact disk read-only memory (CD-ROM), digital versatile disk (DVD), memory stick, floppy disk, mechanical coding device, such as a computer on which instructions are stored The convex structure in the hole card or the groove, and any suitable combination of the above. The computer-readable storage medium used herein is not to be interpreted as a transient signal itself, such as radio waves or other freely propagating electromagnetic waves, electromagnetic waves propagating through waveguides or other transmission media (for example, optical pulses through fiber optic cables), or through wires The transmitted electrical signal.

The computer-readable program instructions described herein can be downloaded from a computer-readable storage medium to various computing / processing devices, or to an external computer or external storage device through a network, such as the Internet, a local area network, a wide area network, and / or a wireless network. The network may include copper transmission cables, fiber optic transmission, wireless transmission, routers, firewalls, switches, gateway computers, and / or edge servers. The network adapter card or network interface in each computing / processing device receives computer-readable program instructions from the network and forwards the computer-readable program instructions for storage in the computer-readable storage medium in each computing / processing device .

Computer program instructions for performing the operations of the present disclosure may be assembly instructions, instruction set architecture (ISA) instructions, machine instructions, machine-related instructions, microcode, firmware instructions, state setting data, or in one or more programming languages Source code or object code written in any combination. The programming languages include object-oriented programming languages-such as Smalltalk, C ++, etc., and conventional procedural programming languages-such as "C" language or similar programming languages. Computer readable program instructions can be executed entirely on the user's computer, partly on the user's computer, as an independent software package, partly on the user's computer and partly on a remote computer, or completely on the remote computer or server carried out. In situations involving remote computers, the remote computer may be connected to the user's computer through any kind of network, including a local area network (LAN) or a wide area network (WAN), or may be connected to an external computer (eg, using an Internet service provider to pass the Internet connection). In some embodiments, electronic circuits, such as programmable logic circuits, field programmable gate arrays (FPGAs) or programmable logic arrays (PLA), can be personalized by utilizing the status information of computer-readable program instructions, which can be Computer-readable program instructions are executed to implement various aspects of the present disclosure.

Various aspects of the present disclosure are described herein with reference to flowcharts and / or block diagrams of methods, devices (systems) and computer program products according to embodiments of the present disclosure. It should be understood that each block of the flowchart and / or block diagram and a combination of blocks in the flowchart and / or block diagram can be implemented by computer-readable program instructions.

These computer-readable program instructions can be provided to the processor of a general-purpose computer, special-purpose computer, or other programmable data processing device, thereby producing a machine that causes these instructions to be executed by the processor of a computer or other programmable data processing device A device that implements the functions / actions specified in one or more blocks in the flowchart and / or block diagram is generated. The computer-readable program instructions may also be stored in a computer-readable storage medium. These instructions enable the computer, programmable data processing apparatus, and / or other devices to work in a specific manner. Therefore, the computer-readable medium storing the instructions includes An article of manufacture that includes instructions to implement various aspects of the functions / acts specified in one or more blocks in the flowchart and / or block diagram.

The computer-readable program instructions can also be loaded onto a computer, other programmable data processing apparatus, or other equipment, so that a series of operating steps are performed on the computer, other programmable data processing apparatus, or other equipment to produce a computer-implemented process , So that the instructions executed on the computer, other programmable data processing device, or other equipment implement the functions / acts specified in one or more blocks in the flowchart and / or block diagram.

The flowchart and block diagrams in the drawings show the possible implementation architecture, functions, and operations of systems, methods, and computer program products according to various embodiments of the present disclosure. In this regard, each block in the flowchart or block diagram may represent a module, program segment, or part of an instruction, and the module, program segment, or part of an instruction contains one or more Executable instructions. In some alternative implementations, the functions marked in the blocks may also occur in an order different from that marked in the drawings. For example, two consecutive blocks can actually be executed substantially in parallel, and sometimes they can also be executed in reverse order, depending on the functions involved. It should also be noted that each block in the block diagrams and / or flowcharts, and combinations of blocks in the block diagrams and / or flowcharts, can be implemented with dedicated hardware-based systems that perform specified functions or actions Or, it can be realized by a combination of dedicated hardware and computer instructions.

The embodiments of the present disclosure have been described above. The above description is exemplary, not exhaustive, and is not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the illustrated embodiments. The selection of terms used herein is intended to best explain the principles, practical applications or technical improvements of the technologies in the embodiments, or to enable other persons of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (94)

1. A self-mobile device, characterized in that the self-mobile device is charged through a wireless charging station, and the wireless charging station is provided with an in-place guidance device, and the self-mobile device determines the wireless by sensing the in-place guidance device The location of the charging station, and the self-mobile device includes:

   A wireless charging receiving module configured to perform a charging operation based on the wireless charging signal received from the wireless charging transmitting module on the wireless charging station;

   A regression guidance module configured to detect guidance information for guiding the self-mobile device to move to the wireless charging station;

   An in-place sensing module configured to sense the in-place guidance device;

   A first control module configured to control the self-mobile device to move to the wireless charging station based on the detected guide information, and configured to adjust the self-mobile device when the in-place guidance device is sensed Operating parameters, the operating parameters include: operating speed and / or operating direction.
2. The self-moving device according to claim 1, wherein the regression guidance module detects working area boundary information, and the first control module is configured to control the self-mobile device to move toward the boundary along the boundary according to the boundary information The wireless charging station moves.
3. The self-mobile device according to claim 2, wherein the wireless charging station is connected to a guide line for generating the boundary information, and the guide information is generated by a power signal transmitted by the guide line; the first The control module is configured to control the self-moving device to move toward the wireless charging station along the guidance line according to the guidance information detected by the regression guidance module.
4. The self-moving device according to claim 3, wherein the regression guide module includes two first detection units respectively disposed on both sides of the base of the self-moving device; the first control module is further configured as When the charging operation needs to be performed, the mobile device is guided to return to the wireless charging station along the guide line according to the phase and / or strength of the magnetic force signals detected by the two first detection units.
5. The self-moving device according to claim 2, wherein the regression guide module includes two second detection units respectively disposed on both sides of the base of the self-moving device; the two second detection units detect The grassland information determines whether it is working area boundary information, and the first control module is configured to control the self-mobile device to move to the wireless charging station along the working area boundary according to the boundary information detected by the regression guidance module.
6. The self-mobile device according to claim 5, wherein the second detection unit is a capacitive sensor.
7. The self-moving device according to claim 1, wherein the in-position guiding device includes a magnet assembly, and the in-place sensing module includes a magnetic detection element; the first control module is configured to detect at the magnetic detection element When the magnetic field signal to the magnet assembly meets the first preset condition, it is determined that the in-place guidance device is detected.
8. The self-moving device according to claim 7, wherein the magnet assembly includes a bar magnet assembly, and the bar magnet assembly includes a magnetic bar or a bar magnet assembly formed by arranging magnetic objects.
9. The self-moving device according to claim 7, wherein the first control module is configured to control the self-moving device when the magnetic detection element detects that the magnetic field signal of the magnet assembly meets a first preset condition Reduce the running speed or control the mobile device to stop running.
10. The self-moving device according to claim 8, wherein when the installation direction of the bar magnet assembly is perpendicular to the running direction of the self-moving device, the bar magnet assembly includes at least two groups, and the first control module It is configured to control the self-moving device to reduce the running speed when the magnetic detection element detects that the magnetic field signal strength of the first group of bar magnet assemblies reaches the first preset threshold, and detects the magnetic field signal strength of the second group of bar magnet assemblies When the second preset threshold is met, the self-mobile device is controlled to stop running.
11. The self-moving device according to claim 8, wherein when the mounting direction of the bar magnet assembly is parallel to the running direction of the self-moving device, the first control module is configured to detect the magnetic field of the magnetic detection element When the signal strength meets the third preset threshold, the self-mobile device is controlled to decrease the running speed, and when the magnetic field signal strength meets the fourth preset threshold, the self-mobile device is controlled to stop running.
12. The self-mobile device according to claim 1, wherein the in-position guidance device includes a wireless signal transmission component, the in-position sensing module includes a wireless signal reception component, or the in-position guidance device includes a wireless signal reception component, The in-place sensing module includes a wireless transmitting component; the first control module is configured to determine that the in-place guidance device is detected when the wireless signal receiving component detects the wireless signal generated by the wireless signal transmitting component.
13. The self-mobile device according to claim 12, wherein the wireless signal transmitting component comprises an RFID transmitter, and the wireless signal receiving component comprises an RFID reader.
14. The self-mobile device according to claim 13, wherein the in-place guidance device is an RFID transmitter, the in-place sensing module is an RFID reader, and the RFID reader detects a radio frequency signal emitted by the RFID transmitter When it is determined that the in-place guidance device is detected.
15. The self-mobile device according to claim 13, wherein the in-place guidance device is an RFID reader, the in-place sensing module is an RFID transmitter, and the wireless charging station and the self-mobile device A communication module including a transmission signal, the RFID reader detects the radio frequency signal emitted by the RFID transmitter, and when the mobile device receives the communication signal transmitted by the wireless charging station, it is determined that the in-place guidance device is detected.
16. The self-mobile device according to claim 1, wherein the in-place guidance device includes a wireless charging transmitting module, the in-place sensing module includes a coil induction module; and the first control module is configured to induce in the coil When the equivalent impedance output by the module changes to a preset range, it is determined that the in-place guidance device is detected.
17. The self-mobile device according to claim 16, wherein the coil sensing module is a metal detection module, and the first control module is connected to the metal detection module to obtain an equivalent impedance output by the metal detection module.
18. The self-mobile device according to claim 16, wherein the coil sensing module includes an LC oscillator, and the first control module is connected to the LC oscillator to obtain an equivalent impedance of the LC oscillator.
19. The self-mobile device according to claim 18, wherein the LC oscillator includes at least one of the following structures:

    A first inductor, a first capacitor, a first resistor and a first oscillator connected in parallel;

    A second inductor and a second oscillator connected in parallel;

    A first coil and a first circuit coupled to the first coil, the first circuit includes a third inductor, a second resistor and a third oscillator connected in series, wherein the first coil is coupled to the third inductor Connect

    A fourth inductor and a third resistor connected in series, and a second capacitor and a third oscillator connected in parallel on both sides of the fourth inductor and the third resistor.
20. The self-mobile device according to claim 1, wherein the regression guidance module is further configured to detect first position information from the mobile device, and the first control module is further configured to The second location information of the charging station and the first location information guide the self-mobile device to move to the wireless charging station.
21. The self-moving device according to claim 1, wherein the in-place guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guide assembly and an in-place assembly, and the in-place sensing module includes A guide component detection unit and an in-place component detection unit that detects the in-place component;

    The first control module is configured to guide the self-mobile device to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and control the self-mobile device to stop running based on the signal detected by the in-place component detection unit.
22. The self-moving device according to claim 21, wherein the guide assembly includes a coil assembly, and the first control module is configured to guide the self-moving device along the coil based on the magnetic force signal detected by the guide assembly detection unit The component moves to the wireless charging transmitter module.
23. The self-moving device according to claim 21, wherein the in-place component includes a sensor component that interacts with the self-moving device or a mechanical structure component that abruptly changes the movement state of the self-moving device.
24. The self-moving device according to claim 1, wherein the in-place guidance device comprises a ring assembly, the ring assembly includes an outer ring assembly and an inner ring assembly, and a wireless charging transmitter module is provided in the inner ring assembly, The in-place sensing module includes an outer ring detection unit that detects an outer ring component and an inner ring detection unit that detects an inner ring component;

    The first control module is configured to adjust the posture of the self-mobile device based on the signal detected by the outer ring detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and based on the signal detected by the inner ring detection unit Control to stop running since the mobile device.
25. The self-mobile device according to claim 24, wherein the outer ring detection unit includes a first outer ring detection unit and a second outer ring detection unit, and the first control module is configured to compare the first outer ring detection unit The signal detected by the ring detection unit and the signal detected by the second outer ring detection unit are controlled to enter the outer ring assembly from the mobile device based on the coincidence of the detected signals.
26. The self-mobile device according to claim 25, wherein the outer ring assembly includes an outer ring coil and a signal generator for generating electrical signals, and the outer ring coil transmits a current to form a magnetic signal, the The first control module is configured to control when the phase or intensity of the magnetic signal of the outer ring coil detected by the first outer ring detection unit matches the phase or intensity of the magnetic signal of the outer ring coil detected by the second outer ring detection unit From the mobile device into the outer loop coil.
27. The self-mobile device according to claim 24, wherein the signal parameters transmitted by the inner ring component and the outer ring component are different.
28. The self-moving device of claim 24, wherein the inner ring assembly includes a magnetic strip, and the inner ring assembly detection unit includes a magnetic detection element.
29. The self-mobile device according to claim 1, wherein the first control module is configured to receive the wireless charging station through the wireless charging receiving module when the self-mobile device enters a coverage area corresponding to a predetermined charging position The wireless charging signal sent.
30. The self-mobile device according to claim 29, wherein the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

    Detecting whether a wireless connection is established between the second communication module and the first communication module;

    If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.
31. The self-mobile device according to claim 29, wherein the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

    Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.
32. A wireless charging station for charging self-mobile devices is characterized by comprising:

    A first power module, which is used to provide power to the wireless charging station;

    A wireless charging transmitting module, which is arranged in the charging area and is configured to transmit a wireless charging signal to the self-mobile device through the power provided by the first power module to charge the self-mobile device;

    The wireless charging station is used in conjunction with a guidance device configured to generate guidance information for guiding the movement from the mobile device to the wireless charging station;

    An in-place guidance device configured for the self-moving device to sense the in-place guidance device to determine the position of the wireless charging station, and adjust when the self-mobile device senses the in-place guidance device Operating parameters of the mobile device, the operating parameters including: operating speed and / or operating direction;

    A second control module configured to control the wireless charging transmitting module to send a wireless charging signal to charge the self-mobile device.
33. The wireless charging station according to claim 32, wherein the guidance device includes a guidance line for generating the guidance information, the wireless charging station is connected to the guidance line, and the guidance information is transmitted by the guidance line The power signal is generated; the self-mobile device controls the self-mobile device to move to the wireless charging station along the guide line based on the detected guidance information.
34. The wireless charging station according to claim 32, wherein the in-place guidance device includes a magnet assembly for the self-moving device to determine that the magnetic field signal of the magnet assembly meets a first predetermined condition as The in-place guidance device is detected.
35. The wireless charging station of claim 34, wherein the magnet assembly comprises a bar magnet assembly, the bar magnet assembly comprising a magnetic strip or a bar magnet assembly formed by arranging magnetic objects.
36. The wireless charging station according to claim 35, wherein when the installation direction of the bar magnet assembly is perpendicular to the running direction of the mobile device, the bar magnet assembly includes at least two groups for The mobile device controls the self-mobile device to reduce the operating speed when it detects that the magnetic field signal strength of the first group of bar magnet assemblies reaches the first preset threshold, and detects that the magnetic field signal strength of the second group of bar magnet assemblies meets the second preset When the threshold value is controlled, the mobile device stops running.
37. The wireless charging station according to claim 35, wherein when the installation direction of the bar magnet assembly is parallel to the running direction of the self-moving device, the self-moving device detects that the magnetic field signal strength of the bar magnet assembly complies with the The third preset threshold controls the self-moving device to reduce the running speed, and detects that the magnetic field signal strength meets the fourth preset threshold to stop the self-moving device from running.
38. The wireless charging station according to claim 32, wherein the in-place guidance device includes a wireless signal transmission component, and the self-moving device includes an in-place sensing module, the in-place sensing module includes a wireless signal receiving component, or The in-place guidance device includes a wireless signal receiving component, and the in-place sensing module includes a wireless transmitting component;

    It is used for the self-mobile device to determine that the in-place guidance device is detected after the wireless signal receiving component detects the wireless signal generated by the wireless signal transmitting component.
39. The wireless charging station of claim 38, wherein the wireless signal transmitting component comprises an RFID transmitter, and the wireless signal receiving component comprises an RFID reader.
40. The wireless charging station according to claim 38, wherein the in-place guidance device is an RFID transmitter, the in-place sensing module is an RFID reader, and the RFID reader detects a radio frequency signal emitted by the RFID transmitter When it is determined that the in-place guidance device is detected.
41. The wireless charging station according to claim 38, wherein the in-place guidance device is an RFID reader, the in-place sensing module is an RFID transmitter, and between the wireless charging station and the mobile device A communication module including a transmission signal, the RFID reader detects the radio frequency signal emitted by the RFID transmitter, and when the mobile device receives the communication signal transmitted by the wireless charging station, it is determined that the in-place guidance device is detected.
42. The wireless charging station according to claim 32, wherein the in-place guidance device includes a wireless charging transmitter module, the self-moving device includes a coil induction module; the self-mobile device outputs the coil induction module, etc. When the effective impedance changes to a preset range, it is determined that the in-place guidance device is detected.
43. The wireless charging station according to claim 42, wherein the coil induction module is a metal detection module, and the equivalent impedance output by the metal detection module is obtained from the mobile device.
44. The wireless charging station of claim 42, wherein the coil induction module includes an LC oscillator, and the equivalent impedance of the LC oscillator is acquired from the mobile device.
45. The wireless charging station of claim 44, wherein the LC oscillator includes at least one of the following structures:

    A first inductor, a first capacitor, a first resistor and a first oscillator connected in parallel;

    A second inductor and a second oscillator connected in parallel;

    A first coil and a first circuit coupled to the first coil, the first circuit includes a third inductor, a second resistor and a third oscillator connected in series, wherein the first coil is coupled to the third inductor Connect

    A fourth inductor and a third resistor connected in series, and a second capacitor and a third oscillator connected in parallel on both sides of the fourth inductor and the third resistor.
46. The wireless charging station according to claim 32, wherein the guidance device includes a positioning module, the self-mobile device is connected to a positioning module, and the self-mobile device uses the second position information of the wireless charging station as a guide Information, using the positioning module to locate the first location information from the mobile device and the second location information to control the autonomous mobile device to move toward the wireless charging station, the location information of the wireless charging station includes a pre-stored location of the wireless charging station .
47. The wireless charging station according to claim 32, wherein the in-place guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guide assembly and an in-place assembly, and the self-moving device includes guidance for detecting the guide assembly A component detection unit and an in-place component detection unit that detects the in-place component;

    The self-moving device guides the self-mobile device to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and controls the self-mobile device to stop running based on the signal detected by the in-place component detection unit.
48. The wireless charging station according to claim 47, wherein the guide assembly includes a coil assembly, and the self-moving device guides the self-mobile device to wirelessly move along the coil assembly based on the magnetic signal detected by the guide assembly detection unit The charging transmitter module moves.
49. The wireless charging station according to claim 47, wherein the in-place component includes a sensor component that interacts with the self-moving device or a mechanical structure component capable of abruptly changing the motion state of the self-moving device.
50. The wireless charging station according to claim 32, wherein the in-place guidance device comprises a ring assembly, the ring assembly includes an outer ring assembly and an inner ring assembly, and the inner ring assembly is provided with a wireless charging transmitter module, The self-moving device includes an outer ring detection unit that detects the outer ring component and an inner ring detection unit that detects the inner ring component;

    The self-moving device adjusts the posture of the self-mobile device based on the signal detected by the outer ring detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and controls the self-movement based on the signal detected by the inner ring detection unit The device stops running.
51. The wireless charging station of claim 50, wherein the outer loop detection unit includes a first outer loop detection unit and a second outer loop detection unit, and the first control module of the mobile device is configured to compare The signal detected by the first outer ring detection unit and the signal detected by the second outer ring detection unit are controlled to enter the outer ring assembly from the mobile device based on the coincidence of the detected signals.
52. The wireless charging station of claim 51, wherein the outer ring assembly includes an outer ring coil and a signal generator for generating a point signal, and the outer ring coil transmits a current to form a magnetic signal, the The first control module is configured to control when the phase or intensity of the magnetic signal of the outer ring coil detected by the first outer ring detection unit matches the phase or intensity of the magnetic signal of the outer ring coil detected by the second outer ring detection unit From the mobile device into the outer loop coil.
53. The wireless charging station of claim 50, wherein the signal parameters transmitted by the inner ring component and the outer ring component are different.
54. The wireless charging station of claim 50, wherein the inner ring assembly includes a magnetic strip, and the inner ring detection unit includes a magnetic detection element.
55. The wireless charging station of claim 32, wherein the wireless charging transmitter module includes a resonant coil assembly.
56. The wireless charging station according to claim 32, characterized in that the wireless charging station comprises a hollow bottom plate.
57. The wireless charging station according to claim 32, wherein the second control module is configured to control the wireless charging transmitting module to send a wireless charging signal to the wireless charging transmitter module when the mobile device enters a coverage area corresponding to a predetermined charging position Described from mobile device charging.
58. The wireless charging station of claim 56, wherein the wireless charging station includes a second communication module, and the self-mobile device includes a first communication module;

    Detecting whether a wireless connection is established between the second communication module and the first communication module;

    If the second communication module successfully establishes the wireless connection with the first communication module, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.
59. The wireless charging station of claim 56, wherein the wireless charging station includes a second communication module, and the self-mobile device includes a first communication module;

    Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.
60. A wireless charging station for charging self-mobile devices is characterized by comprising:

    A first power module, which is used to provide power to the wireless charging station;

    A wireless charging transmitting module configured to transmit a wireless charging signal to the self-mobile device through the power provided by the first power module to charge the self-mobile device;

    The wireless charging station is used in conjunction with a guidance device, and the guidance device is configured to generate guidance information for guiding the movement from the mobile device to the wireless charging station;

    A guiding device in place, which includes a ring assembly including an outer ring assembly and an inner ring assembly disposed inside the outer ring assembly, the wireless charging transmitter module is located in the inner ring assembly, and the self-mobile device Adjust the posture of the self-mobile device based on the sensed signal of the outer ring component to guide the self-mobile device to move toward the wireless charging transmitting module, and control the self-mobile device to reduce the running speed based on the sensed signal of the inner ring component or Stop running

    A second control module configured to control the wireless charging transmitting module to send a wireless charging signal to charge the self-mobile device.
61. An automatic working system, characterized by comprising a self-mobile device according to any one of claims 1-31 and a wireless charging station according to any one of claims 32-60.
62. A wireless charging method for an automatic working system, which includes a self-mobile device and a wireless charging station, characterized in that the wireless charging station is used in conjunction with a guidance device for generating a guidance signal, and the wireless charging station There is a guiding device in place, the method includes:

    Detect the pilot signal;

    Controlling the self-mobile device to move toward the wireless charging station when the guidance signal is detected;

    Sensing a guiding device in place on the wireless charging station;

    Adjusting the operating parameters of the self-moving device when the in-place guidance device is sensed, the operating parameters including: operating speed and / or operating direction;

    The wireless charging station is controlled to transmit a wireless charging signal to charge the mobile device.
63. The method of claim 62, wherein the in-place guidance device includes a magnet assembly, and the sensing in-place guidance device provided on the wireless charging station includes:

    Detecting the magnetic field signal of the magnet assembly by a magnetic detection element;

    When the magnetic detection element detects that the magnetic field signal of the magnet assembly meets the first preset condition, it is determined that the in-place guidance device is detected.
64. The method of claim 62, wherein the in-place guidance device includes a wireless signal transmission component, and the sensing in-place guidance device provided on the wireless charging station includes:

    When the wireless signal generated by the wireless signal transmitting component is detected by the wireless signal receiving component, it is determined that the in-place guidance device is detected.
65. The method of claim 62, wherein the in-place guidance device includes a wireless signal receiving component, and the sensing in-place guidance device provided on the wireless charging station includes:

    When the wireless signal generated by the wireless signal transmitting component is detected by the wireless signal receiving component, it is determined that the in-place guidance device is detected.
66. The method according to claim 62, wherein the in-place guidance device includes a wireless charging transmitting module, and the sensing in-place guidance device provided on the wireless charging station includes:

    When the equivalent impedance output by the coil induction module changes to a preset range, it is determined that the in-place guidance device is detected.
67. The method according to claim 62, wherein the in-place guidance device includes an auxiliary coil assembly, the auxiliary coil assembly includes a guide assembly and an in-place assembly, and the sensing in-place guidance provided on the wireless charging station The device includes:

    The self-mobile device is guided to move to the wireless charging transmitting module based on the signal detected by the guide component detection unit, and the self-mobile device is controlled to stop running based on the signal detected by the in-place component detection unit.
68. The method according to claim 62, wherein the in-place guidance device includes a ring assembly, the ring assembly includes an outer ring assembly and an inner ring assembly, a wireless charging transmitter module is provided in the inner ring assembly, and the The sensing in-place guidance device provided on the wireless charging station includes:

    The posture of the self-mobile device is adjusted based on the signal detected by the outer loop detection unit to guide the self-mobile device to move toward the wireless charging transmitting module, and the self-mobile device is controlled to stop running based on the signal detected by the inner loop detection unit.
69. The method of claim 62, further comprising:

    When the self-mobile device enters the coverage area corresponding to the predetermined charging position, the wireless charging signal sent by the wireless charging station is received by the wireless charging receiving module.
70. A wireless charging method for an automatic working system, which includes a self-mobile device and a wireless charging station, characterized in that the wireless charging station is used in conjunction with a guidance device for generating a guidance signal, and the wireless charging station There is a guiding device in place, the method includes:

    Detect the pilot signal;

    Controlling the self-mobile device to move toward the wireless charging station when the guidance signal is detected;

    Sensing an in-place guidance device provided on the wireless charging station, wherein the in-place guidance device includes a ring assembly including an outer ring assembly and an inner ring assembly disposed inside the outer ring assembly, and the wireless transmission module is located Inside the inner ring assembly;

    Adjust the attitude of the self-mobile device based on the sensed signal of the outer ring component to guide the self-mobile device to move toward the wireless transmitting module, and control the self-mobile device to reduce the running speed or stop based on the sensed signal of the inner ring component run;

    The wireless charging station is controlled to transmit a wireless charging signal to charge the mobile device.
71. A self-mobile device, which is charged through a wireless charging station, is characterized by comprising:

    A wireless charging receiving module configured to perform a charging operation based on the wireless charging signal received from the wireless charging station;

    The first control module is configured to receive the wireless charging signal sent by the wireless charging station through the wireless charging receiving module when the self-mobile device enters the coverage corresponding to the predetermined charging position.
72. The self-mobile device according to claim 71, wherein the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

    Detecting whether a wireless connection is established between the second communication module and the first communication module;

    If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.
73. The self-mobile device according to claim 71, wherein the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module;

    Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.
74. The self-mobile device according to claim 71, wherein the self-mobile device includes a first request module, and the first request module sends a request signal to the wireless charging station;

    After the wireless charging station receives the request signal, the wireless charging station charges the self-mobile device.
75. The self-mobile device according to claim 71, characterized in that the self-mobile device includes a response module, the wireless charging station sends a request signal to the self-mobile device, and the response module sends according to the wireless charging station The request signal returns the response signal;

    After the wireless charging station receives the response signal matched with the request signal by the response module, the wireless charging station charges the self-mobile device.
76. The self-mobile device according to claim 72, wherein after the self-mobile device enters the coverage range corresponding to the predetermined charging position, the first control module is configured to control the self-mobile device to reduce the operating speed and move to The predetermined charging location.
77. The self-mobile device according to claim 72, wherein after the self-mobile device enters the coverage range corresponding to the predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.
78. The self-mobile device according to claim 72, further comprising a detection module, during the charging process, the detection module detects whether charging of the self-mobile device is completed, and if the charging is completed, controls the The wireless charging station enters a low power consumption mode.
79. A wireless charging station for charging self-mobile devices is characterized by comprising:

    A first power module, which is used to provide power to the wireless charging station;

    A wireless charging transmitting module configured to transmit a wireless charging signal to the self-mobile device through the power provided by the power supply module to charge the self-mobile device;

    A second control module configured to switch on the first power module and the wireless charging transmitting module when the self-mobile device enters the coverage range corresponding to the predetermined charging position to start the wireless charging transmitting module to the self-mobile device Transmit wireless charging signal.
80. The wireless charging station of claim 79, wherein the wireless charging station includes a second communication module, and the self-mobile device includes a first communication module;

    Detecting whether a wireless connection is established between the second communication module and the first communication module;

    If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.
81. The wireless charging station of claim 79, wherein the wireless charging station includes a second communication module, and the self-mobile device includes a first communication module;

    Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.
82. The wireless charging station of claim 79, wherein the wireless charging station includes a receiving module, and the self-mobile device sends a request signal to the wireless charging station;

    After the receiving module receives the request signal, the second control module is configured to charge the self-mobile device to the wireless charging station.
83. The wireless charging station according to claim 79, wherein the wireless charging station includes a second request module and a receiving module, and the second request module sends a request signal to the self-mobile device;

    After the receiving module receives the response signal matched by the self-mobile device and matching the request signal, the second control module is configured to control the wireless charging station to charge the self-mobile device.
84. The wireless charging station according to claim 79, wherein after the self-mobile device enters the coverage range corresponding to the predetermined charging position, the second control module controls the self-mobile device to decrease the running speed and move to the predetermined charging position.
85. The wireless charging station according to claim 79, wherein after the self-mobile device enters a coverage area corresponding to a predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.
86. The wireless charging station according to claim 79, further comprising a detection module, during the charging process, the detection module detects whether the charging of the self-mobile device is completed, and if the charging is completed, controls the The wireless charging station enters a low power consumption mode.
87. An automatic working system, characterized by comprising a wireless charging station according to any one of claims 79-86 and a self-mobile device according to any one of claims 74-78.
88. A charging method of an automatic working system, which is applied in a self-working system, which includes a self-mobile device and a wireless charging station that performs a charging operation for the self-mobile device, characterized in that the method includes :

    Determining whether the self-mobile device enters the coverage range corresponding to the predetermined charging location;

    If yes, the wireless charging transmitting module is activated to transmit a wireless charging signal to charge the self-mobile device.
89. The method according to claim 88, wherein the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module; the determination corresponds to whether the self-mobile device enters a predetermined charging location The coverage includes:

    Detecting whether a wireless connection is established between the second communication module and the first communication module;

    If the second communication module and the first communication module successfully establish the wireless connection, it is determined that the self-mobile device enters a coverage range corresponding to a predetermined charging location.
90. The method according to claim 88, wherein the self-mobile device includes a first communication module, and the wireless charging station includes a second communication module; the determination corresponds to whether the self-mobile device enters a predetermined charging location The coverage includes:

    Establish a wireless connection between the second communication module and the first communication module, detect the signal strength of the wireless connection, and if the signal strength of the wireless connection reaches a preset signal strength, determine the self-moving The device enters the coverage area corresponding to the predetermined charging location.
91. The method according to claim 88, wherein the wireless charging station includes a receiving module, the method further comprising:

    The self-mobile device sends a request signal to the wireless charging station;

    After the receiving module receives the request signal, the wireless charging station charges the self-mobile device.
92. The method according to claim 88, wherein the self-mobile device includes a response module, the method further comprising:

    The wireless charging station sends a request signal to the self-mobile device, and the response module returns a response signal according to the request signal sent by the wireless charging station;

    After the wireless charging station receives the response signal matched with the request signal by the response module, the wireless charging station charges the self-mobile device.
93. The method of claim 88, further comprising:

    After the self-mobile device enters the coverage area corresponding to the predetermined charging position, the wireless charging station is controlled to turn on its own wireless charging transmitting module.
94. The method of claim 88, further comprising:

    During the charging process, it is detected whether the charging of the self-mobile device is completed;

    If the charging is completed, the wireless charging station is controlled to enter a low power consumption mode.

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